promoting problem solving in the classroom

Classroom Q&A

With larry ferlazzo.

In this EdWeek blog, an experiment in knowledge-gathering, Ferlazzo will address readers’ questions on classroom management, ELL instruction, lesson planning, and other issues facing teachers. Send your questions to [email protected]. Read more from this blog.

Eight Instructional Strategies for Promoting Critical Thinking

promoting problem solving in the classroom

(This is the first post in a three-part series.)

The new question-of-the-week is:

What is critical thinking and how can we integrate it into the classroom?

This three-part series will explore what critical thinking is, if it can be specifically taught and, if so, how can teachers do so in their classrooms.

Today’s guests are Dara Laws Savage, Patrick Brown, Meg Riordan, Ph.D., and Dr. PJ Caposey. Dara, Patrick, and Meg were also guests on my 10-minute BAM! Radio Show . You can also find a list of, and links to, previous shows here.

You might also be interested in The Best Resources On Teaching & Learning Critical Thinking In The Classroom .

Current Events

Dara Laws Savage is an English teacher at the Early College High School at Delaware State University, where she serves as a teacher and instructional coach and lead mentor. Dara has been teaching for 25 years (career preparation, English, photography, yearbook, newspaper, and graphic design) and has presented nationally on project-based learning and technology integration:

There is so much going on right now and there is an overload of information for us to process. Did you ever stop to think how our students are processing current events? They see news feeds, hear news reports, and scan photos and posts, but are they truly thinking about what they are hearing and seeing?

I tell my students that my job is not to give them answers but to teach them how to think about what they read and hear. So what is critical thinking and how can we integrate it into the classroom? There are just as many definitions of critical thinking as there are people trying to define it. However, the Critical Think Consortium focuses on the tools to create a thinking-based classroom rather than a definition: “Shape the climate to support thinking, create opportunities for thinking, build capacity to think, provide guidance to inform thinking.” Using these four criteria and pairing them with current events, teachers easily create learning spaces that thrive on thinking and keep students engaged.

One successful technique I use is the FIRE Write. Students are given a quote, a paragraph, an excerpt, or a photo from the headlines. Students are asked to F ocus and respond to the selection for three minutes. Next, students are asked to I dentify a phrase or section of the photo and write for two minutes. Third, students are asked to R eframe their response around a specific word, phrase, or section within their previous selection. Finally, students E xchange their thoughts with a classmate. Within the exchange, students also talk about how the selection connects to what we are covering in class.

There was a controversial Pepsi ad in 2017 involving Kylie Jenner and a protest with a police presence. The imagery in the photo was strikingly similar to a photo that went viral with a young lady standing opposite a police line. Using that image from a current event engaged my students and gave them the opportunity to critically think about events of the time.

Here are the two photos and a student response:

F - Focus on both photos and respond for three minutes

In the first picture, you see a strong and courageous black female, bravely standing in front of two officers in protest. She is risking her life to do so. Iesha Evans is simply proving to the world she does NOT mean less because she is black … and yet officers are there to stop her. She did not step down. In the picture below, you see Kendall Jenner handing a police officer a Pepsi. Maybe this wouldn’t be a big deal, except this was Pepsi’s weak, pathetic, and outrageous excuse of a commercial that belittles the whole movement of people fighting for their lives.

I - Identify a word or phrase, underline it, then write about it for two minutes

A white, privileged female in place of a fighting black woman was asking for trouble. A struggle we are continuously fighting every day, and they make a mockery of it. “I know what will work! Here Mr. Police Officer! Drink some Pepsi!” As if. Pepsi made a fool of themselves, and now their already dwindling fan base continues to ever shrink smaller.

R - Reframe your thoughts by choosing a different word, then write about that for one minute

You don’t know privilege until it’s gone. You don’t know privilege while it’s there—but you can and will be made accountable and aware. Don’t use it for evil. You are not stupid. Use it to do something. Kendall could’ve NOT done the commercial. Kendall could’ve released another commercial standing behind a black woman. Anything!

Exchange - Remember to discuss how this connects to our school song project and our previous discussions?

This connects two ways - 1) We want to convey a strong message. Be powerful. Show who we are. And Pepsi definitely tried. … Which leads to the second connection. 2) Not mess up and offend anyone, as had the one alma mater had been linked to black minstrels. We want to be amazing, but we have to be smart and careful and make sure we include everyone who goes to our school and everyone who may go to our school.

As a final step, students read and annotate the full article and compare it to their initial response.

Using current events and critical-thinking strategies like FIRE writing helps create a learning space where thinking is the goal rather than a score on a multiple-choice assessment. Critical-thinking skills can cross over to any of students’ other courses and into life outside the classroom. After all, we as teachers want to help the whole student be successful, and critical thinking is an important part of navigating life after they leave our classrooms.

‘Before-Explore-Explain’

Patrick Brown is the executive director of STEM and CTE for the Fort Zumwalt school district in Missouri and an experienced educator and author :

Planning for critical thinking focuses on teaching the most crucial science concepts, practices, and logical-thinking skills as well as the best use of instructional time. One way to ensure that lessons maintain a focus on critical thinking is to focus on the instructional sequence used to teach.

Explore-before-explain teaching is all about promoting critical thinking for learners to better prepare students for the reality of their world. What having an explore-before-explain mindset means is that in our planning, we prioritize giving students firsthand experiences with data, allow students to construct evidence-based claims that focus on conceptual understanding, and challenge students to discuss and think about the why behind phenomena.

Just think of the critical thinking that has to occur for students to construct a scientific claim. 1) They need the opportunity to collect data, analyze it, and determine how to make sense of what the data may mean. 2) With data in hand, students can begin thinking about the validity and reliability of their experience and information collected. 3) They can consider what differences, if any, they might have if they completed the investigation again. 4) They can scrutinize outlying data points for they may be an artifact of a true difference that merits further exploration of a misstep in the procedure, measuring device, or measurement. All of these intellectual activities help them form more robust understanding and are evidence of their critical thinking.

In explore-before-explain teaching, all of these hard critical-thinking tasks come before teacher explanations of content. Whether we use discovery experiences, problem-based learning, and or inquiry-based activities, strategies that are geared toward helping students construct understanding promote critical thinking because students learn content by doing the practices valued in the field to generate knowledge.

An Issue of Equity

Meg Riordan, Ph.D., is the chief learning officer at The Possible Project, an out-of-school program that collaborates with youth to build entrepreneurial skills and mindsets and provides pathways to careers and long-term economic prosperity. She has been in the field of education for over 25 years as a middle and high school teacher, school coach, college professor, regional director of N.Y.C. Outward Bound Schools, and director of external research with EL Education:

Although critical thinking often defies straightforward definition, most in the education field agree it consists of several components: reasoning, problem-solving, and decisionmaking, plus analysis and evaluation of information, such that multiple sides of an issue can be explored. It also includes dispositions and “the willingness to apply critical-thinking principles, rather than fall back on existing unexamined beliefs, or simply believe what you’re told by authority figures.”

Despite variation in definitions, critical thinking is nonetheless promoted as an essential outcome of students’ learning—we want to see students and adults demonstrate it across all fields, professions, and in their personal lives. Yet there is simultaneously a rationing of opportunities in schools for students of color, students from under-resourced communities, and other historically marginalized groups to deeply learn and practice critical thinking.

For example, many of our most underserved students often spend class time filling out worksheets, promoting high compliance but low engagement, inquiry, critical thinking, or creation of new ideas. At a time in our world when college and careers are critical for participation in society and the global, knowledge-based economy, far too many students struggle within classrooms and schools that reinforce low-expectations and inequity.

If educators aim to prepare all students for an ever-evolving marketplace and develop skills that will be valued no matter what tomorrow’s jobs are, then we must move critical thinking to the forefront of classroom experiences. And educators must design learning to cultivate it.

So, what does that really look like?

Unpack and define critical thinking

To understand critical thinking, educators need to first unpack and define its components. What exactly are we looking for when we speak about reasoning or exploring multiple perspectives on an issue? How does problem-solving show up in English, math, science, art, or other disciplines—and how is it assessed? At Two Rivers, an EL Education school, the faculty identified five constructs of critical thinking, defined each, and created rubrics to generate a shared picture of quality for teachers and students. The rubrics were then adapted across grade levels to indicate students’ learning progressions.

At Avenues World School, critical thinking is one of the Avenues World Elements and is an enduring outcome embedded in students’ early experiences through 12th grade. For instance, a kindergarten student may be expected to “identify cause and effect in familiar contexts,” while an 8th grader should demonstrate the ability to “seek out sufficient evidence before accepting a claim as true,” “identify bias in claims and evidence,” and “reconsider strongly held points of view in light of new evidence.”

When faculty and students embrace a common vision of what critical thinking looks and sounds like and how it is assessed, educators can then explicitly design learning experiences that call for students to employ critical-thinking skills. This kind of work must occur across all schools and programs, especially those serving large numbers of students of color. As Linda Darling-Hammond asserts , “Schools that serve large numbers of students of color are least likely to offer the kind of curriculum needed to ... help students attain the [critical-thinking] skills needed in a knowledge work economy. ”

So, what can it look like to create those kinds of learning experiences?

Designing experiences for critical thinking

After defining a shared understanding of “what” critical thinking is and “how” it shows up across multiple disciplines and grade levels, it is essential to create learning experiences that impel students to cultivate, practice, and apply these skills. There are several levers that offer pathways for teachers to promote critical thinking in lessons:

1.Choose Compelling Topics: Keep it relevant

A key Common Core State Standard asks for students to “write arguments to support claims in an analysis of substantive topics or texts using valid reasoning and relevant and sufficient evidence.” That might not sound exciting or culturally relevant. But a learning experience designed for a 12th grade humanities class engaged learners in a compelling topic— policing in America —to analyze and evaluate multiple texts (including primary sources) and share the reasoning for their perspectives through discussion and writing. Students grappled with ideas and their beliefs and employed deep critical-thinking skills to develop arguments for their claims. Embedding critical-thinking skills in curriculum that students care about and connect with can ignite powerful learning experiences.

2. Make Local Connections: Keep it real

At The Possible Project , an out-of-school-time program designed to promote entrepreneurial skills and mindsets, students in a recent summer online program (modified from in-person due to COVID-19) explored the impact of COVID-19 on their communities and local BIPOC-owned businesses. They learned interviewing skills through a partnership with Everyday Boston , conducted virtual interviews with entrepreneurs, evaluated information from their interviews and local data, and examined their previously held beliefs. They created blog posts and videos to reflect on their learning and consider how their mindsets had changed as a result of the experience. In this way, we can design powerful community-based learning and invite students into productive struggle with multiple perspectives.

3. Create Authentic Projects: Keep it rigorous

At Big Picture Learning schools, students engage in internship-based learning experiences as a central part of their schooling. Their school-based adviser and internship-based mentor support them in developing real-world projects that promote deeper learning and critical-thinking skills. Such authentic experiences teach “young people to be thinkers, to be curious, to get from curiosity to creation … and it helps students design a learning experience that answers their questions, [providing an] opportunity to communicate it to a larger audience—a major indicator of postsecondary success.” Even in a remote environment, we can design projects that ask more of students than rote memorization and that spark critical thinking.

Our call to action is this: As educators, we need to make opportunities for critical thinking available not only to the affluent or those fortunate enough to be placed in advanced courses. The tools are available, let’s use them. Let’s interrogate our current curriculum and design learning experiences that engage all students in real, relevant, and rigorous experiences that require critical thinking and prepare them for promising postsecondary pathways.

Critical Thinking & Student Engagement

Dr. PJ Caposey is an award-winning educator, keynote speaker, consultant, and author of seven books who currently serves as the superintendent of schools for the award-winning Meridian CUSD 223 in northwest Illinois. You can find PJ on most social-media platforms as MCUSDSupe:

When I start my keynote on student engagement, I invite two people up on stage and give them each five paper balls to shoot at a garbage can also conveniently placed on stage. Contestant One shoots their shot, and the audience gives approval. Four out of 5 is a heckuva score. Then just before Contestant Two shoots, I blindfold them and start moving the garbage can back and forth. I usually try to ensure that they can at least make one of their shots. Nobody is successful in this unfair environment.

I thank them and send them back to their seats and then explain that this little activity was akin to student engagement. While we all know we want student engagement, we are shooting at different targets. More importantly, for teachers, it is near impossible for them to hit a target that is moving and that they cannot see.

Within the world of education and particularly as educational leaders, we have failed to simplify what student engagement looks like, and it is impossible to define or articulate what student engagement looks like if we cannot clearly articulate what critical thinking is and looks like in a classroom. Because, simply, without critical thought, there is no engagement.

The good news here is that critical thought has been defined and placed into taxonomies for decades already. This is not something new and not something that needs to be redefined. I am a Bloom’s person, but there is nothing wrong with DOK or some of the other taxonomies, either. To be precise, I am a huge fan of Daggett’s Rigor and Relevance Framework. I have used that as a core element of my practice for years, and it has shaped who I am as an instructional leader.

So, in order to explain critical thought, a teacher or a leader must familiarize themselves with these tried and true taxonomies. Easy, right? Yes, sort of. The issue is not understanding what critical thought is; it is the ability to integrate it into the classrooms. In order to do so, there are a four key steps every educator must take.

Integrating critical thought/rigor into a lesson does not happen by chance, it happens by design. Planning for critical thought and engagement is much different from planning for a traditional lesson. In order to plan for kids to think critically, you have to provide a base of knowledge and excellent prompts to allow them to explore their own thinking in order to analyze, evaluate, or synthesize information.
SIDE NOTE – Bloom’s verbs are a great way to start when writing objectives, but true planning will take you deeper than this.

QUESTIONING

If the questions and prompts given in a classroom have correct answers or if the teacher ends up answering their own questions, the lesson will lack critical thought and rigor.
Script five questions forcing higher-order thought prior to every lesson. Experienced teachers may not feel they need this, but it helps to create an effective habit.
If lessons are rigorous and assessments are not, students will do well on their assessments, and that may not be an accurate representation of the knowledge and skills they have mastered. If lessons are easy and assessments are rigorous, the exact opposite will happen. When deciding to increase critical thought, it must happen in all three phases of the game: planning, instruction, and assessment.

TALK TIME / CONTROL

To increase rigor, the teacher must DO LESS. This feels counterintuitive but is accurate. Rigorous lessons involving tons of critical thought must allow for students to work on their own, collaborate with peers, and connect their ideas. This cannot happen in a silent room except for the teacher talking. In order to increase rigor, decrease talk time and become comfortable with less control. Asking questions and giving prompts that lead to no true correct answer also means less control. This is a tough ask for some teachers. Explained differently, if you assign one assignment and get 30 very similar products, you have most likely assigned a low-rigor recipe. If you assign one assignment and get multiple varied products, then the students have had a chance to think deeply, and you have successfully integrated critical thought into your classroom.

Thanks to Dara, Patrick, Meg, and PJ for their contributions!

Please feel free to leave a comment with your reactions to the topic or directly to anything that has been said in this post.

Consider contributing a question to be answered in a future post. You can send one to me at [email protected] . When you send it in, let me know if I can use your real name if it’s selected or if you’d prefer remaining anonymous and have a pseudonym in mind.

You can also contact me on Twitter at @Larryferlazzo .

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Center for Teaching

Teaching problem solving.

Print Version

Tips and Techniques

Expert vs. novice problem solvers, communicate.

Have students identify specific problems, difficulties, or confusions . Don’t waste time working through problems that students already understand.
If students are unable to articulate their concerns, determine where they are having trouble by asking them to identify the specific concepts or principles associated with the problem.
In a one-on-one tutoring session, ask the student to work his/her problem out loud . This slows down the thinking process, making it more accurate and allowing you to access understanding.
When working with larger groups you can ask students to provide a written “two-column solution.” Have students write up their solution to a problem by putting all their calculations in one column and all of their reasoning (in complete sentences) in the other column. This helps them to think critically about their own problem solving and helps you to more easily identify where they may be having problems. Two-Column Solution (Math) Two-Column Solution (Physics)

Encourage Independence

Model the problem solving process rather than just giving students the answer. As you work through the problem, consider how a novice might struggle with the concepts and make your thinking clear
Have students work through problems on their own. Ask directing questions or give helpful suggestions, but provide only minimal assistance and only when needed to overcome obstacles.
Don’t fear group work ! Students can frequently help each other, and talking about a problem helps them think more critically about the steps needed to solve the problem. Additionally, group work helps students realize that problems often have multiple solution strategies, some that might be more effective than others

Be sensitive

Frequently, when working problems, students are unsure of themselves. This lack of confidence may hamper their learning. It is important to recognize this when students come to us for help, and to give each student some feeling of mastery. Do this by providing positive reinforcement to let students know when they have mastered a new concept or skill.

Encourage Thoroughness and Patience

Try to communicate that the process is more important than the answer so that the student learns that it is OK to not have an instant solution. This is learned through your acceptance of his/her pace of doing things, through your refusal to let anxiety pressure you into giving the right answer, and through your example of problem solving through a step-by step process.

Experts (teachers) in a particular field are often so fluent in solving problems from that field that they can find it difficult to articulate the problem solving principles and strategies they use to novices (students) in their field because these principles and strategies are second nature to the expert. To teach students problem solving skills, a teacher should be aware of principles and strategies of good problem solving in his or her discipline .

The mathematician George Polya captured the problem solving principles and strategies he used in his discipline in the book How to Solve It: A New Aspect of Mathematical Method (Princeton University Press, 1957). The book includes a summary of Polya’s problem solving heuristic as well as advice on the teaching of problem solving.

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Trauma-informed practices in schools, teacher well-being, cultivating diversity, equity, & inclusion, integrating technology in the classroom, social-emotional development, covid-19 resources, invest in resilience: summer toolkit, civics & resilience, all toolkits, degree programs, trauma-informed professional development, teacher licensure & certification, how to become - career information, classroom management, instructional design, lifestyle & self-care, online higher ed teaching, current events, 5 problem-solving activities for the classroom.

5 Problem-Solving Activities for the Classroom

Problem-solving skills are necessary in all areas of life, and classroom problem solving activities can be a great way to get students prepped and ready to solve real problems in real life scenarios. Whether in school, work or in their social relationships, the ability to critically analyze a problem, map out all its elements and then prepare a workable solution is one of the most valuable skills one can acquire in life.

Educating your students about problem solving skills from an early age in school can be facilitated through classroom problem solving activities. Such endeavors encourage cognitive as well as social development, and can equip students with the tools they’ll need to address and solve problems throughout the rest of their lives. Here are five classroom problem solving activities your students are sure to benefit from as well as enjoy doing:

1. Brainstorm bonanza

Having your students create lists related to whatever you are currently studying can be a great way to help them to enrich their understanding of a topic while learning to problem-solve. For example, if you are studying a historical, current or fictional event that did not turn out favorably, have your students brainstorm ways that the protagonist or participants could have created a different, more positive outcome. They can brainstorm on paper individually or on a chalkboard or white board in front of the class.

2. Problem-solving as a group

Have your students create and decorate a medium-sized box with a slot in the top. Label the box “The Problem-Solving Box.” Invite students to anonymously write down and submit any problem or issue they might be having at school or at home, ones that they can’t seem to figure out on their own. Once or twice a week, have a student draw one of the items from the box and read it aloud. Then have the class as a group figure out the ideal way the student can address the issue and hopefully solve it.

3. Clue me in

This fun detective game encourages problem-solving, critical thinking and cognitive development. Collect a number of items that are associated with a specific profession, social trend, place, public figure, historical event, animal, etc. Assemble actual items (or pictures of items) that are commonly associated with the target answer. Place them all in a bag (five-10 clues should be sufficient.) Then have a student reach into the bag and one by one pull out clues. Choose a minimum number of clues they must draw out before making their first guess (two- three). After this, the student must venture a guess after each clue pulled until they guess correctly. See how quickly the student is able to solve the riddle.

4. Survivor scenarios

Create a pretend scenario for students that requires them to think creatively to make it through. An example might be getting stranded on an island, knowing that help will not arrive for three days. The group has a limited amount of food and water and must create shelter from items around the island. Encourage working together as a group and hearing out every child that has an idea about how to make it through the three days as safely and comfortably as possible.

5. Moral dilemma

Create a number of possible moral dilemmas your students might encounter in life, write them down, and place each item folded up in a bowl or bag. Some of the items might include things like, “I saw a good friend of mine shoplifting. What should I do?” or “The cashier gave me an extra $1.50 in change after I bought candy at the store. What should I do?” Have each student draw an item from the bag one by one, read it aloud, then tell the class their answer on the spot as to how they would handle the situation.

Classroom problem solving activities need not be dull and routine. Ideally, the problem solving activities you give your students will engage their senses and be genuinely fun to do. The activities and lessons learned will leave an impression on each child, increasing the likelihood that they will take the lesson forward into their everyday lives.

Thinking Classrooms: How To Promote Critical Thinking In Class

The Thinking Classroom is an approach to teaching that prioritizes the development of students’ critical thinking skills. In this type of classroom, the teacher acts as a facilitator rather than a traditional lecturer. Students are encouraged to actively engage with the material and collaborate with their peers.

The key to a Thinking Classroom is to focus on the process of learning rather than simply the acquisition of knowledge. This means that teachers must create opportunities for students to think critically, solve problems, and reflect on their learning.

We’ve rounded up the 14 practices of a Thinking Classroom below.

What are the 14 Practices of a Thinking Classroom?

The fourteen principles of a Thinking Classroom are designed to promote a classroom environment that encourages critical thinking, problem-solving, and collaboration.

Here’s a summary of each principle to help teachers create an engaging and effective learning environment:

1. Classroom Culture of Thinking

Create a classroom culture that values thinking, learning, and intellectual development. Start with thinking tasks that are separate from your curriculum. This eases the transition to everyday thinking classroom activities. It’s hard for students to think deeper and for longer periods, so this transition should be gradual. You can start with non-curricular tasks as an ice breaker at the beginning of the school year.

2. Opportunities to Think in Groups

Provide opportunities for students to think and engage in meaningful group learning experiences. The Thinking Classroom practices emphasize “visibly random groups” that change frequently. This reduces social anxiety in the group and decreases communication barriers.

3. Vertical and Non-permanant Workspaces

You may have noticed that the traditional method of having students sit at their desks and take notes is only sometimes the best way to promote active thinking in your classroom. Recent research has shown that students are more engaged and productive when standing and working on vertical non-permanent surfaces (VNPSs) like whiteboards, blackboards, or windows. The fact that the surface is non-permanent encourages risk-taking and experimentation, while the vertical orientation prevents students from disengaging.

4. Room Layout

Research has shown that traditional, front-facing classrooms promote passive learning. At the same time, a more flexible, de-fronted setup—where students are free to face any direction—can be much more effective in promoting active thinking and engagement. So when designing your classroom layout, it’s essential to consider how the physical space can support the learning you want to see.

5. Answer Questions that Promote Thinking

You answer hundreds of questions each day in class. But not all of the questions encourage your students to keep thinking. Here are the common types:

Proximity questions: Questions students ask because you’re close by and convenient.
Stop-thinking questions: Questions students ask so they can mark a task complete. (i.e., Is this right?)
Keep-thinking questions: Questions that help them along, so they can continue working through a task.

Answer only questions that keep students thinking.

6. Give Tasks in the Right Manner

Give tasks early in class while students are standing around a teacher. Give verbal tasks, and avoid visual cues that promote passive learning. This differs from the traditional manner of giving examples from the textbook or a worksheet.

7. Homework

Stop giving homework and instead give students opportunities to check their understanding. Make it optional so students can freely engage with authentic practice.

8. Promote Student Autonomy

As step 5 outlines, don’t solve problems for students. Let them struggle so they build confidence in their independence. This may mean asking a peer for help or looking around the room for a hint. When students are on their own, they take ownership of their learning.

9. Give Support So Students Can Learn at Their Own Pace

Encourage students to learn at their own pace by creating hints, extensions, and practice that meets them where they are in their learning. This is different from the typical guided practice that occurs in most classrooms.

10. Consolidate Lessons

Consolidation is crucial to help students combine different parts of a task or activity and ultimately form a more comprehensive understanding of the concept taught. Traditionally, teachers have relied on methods like showing, telling, or explaining to help students achieve their learning objectives.

In a thinking classroom, consolidation takes a different approach. Instead of relying on teacher-led instruction, consolidation works upward from the basic foundation of a concept. By drawing on the student work produced during their thinking on a common set of tasks, teachers can help students develop a deeper understanding of the concept.

To facilitate this process, teachers should provide open-ended questions, encourage peer-to-peer discussions, or engage in activities that allow students to explore and experiment with the concept taught.

11. Give Students Autonomy Over Notes

Only one in five students review their notes again after taking them in class. Give students the option of choosing which notes to take while learning. They are more likely to refer back to notes later.

12. Evaluate Values That Matter Most

If you want your students to participate, take risks, and persevere in the classroom, you should incorporate these values into evaluations. Assessment should go beyond curriculum knowledge.

13. Bring Students into Formative Assessment

Your students need to understand where they are and where they need to be with their learning. This means that they need to be a partner in formative assessment . Like students taking the lead over homework, they need to take the lead on owning their success in formative assessment.

14. Assessment Needs to Connect to an Outcome

Use assessments that measure and value thinking and understanding, not just rote memorization. This may look like standards-based grading. Students need to understand what they know and don’t know after they complete an assessment.

By implementing these principles, teachers can create a dynamic and engaging classroom that promotes deep learning and helps students develop the critical thinking and problem-solving skills they need to succeed in school and beyond.

TeacherMade helps teachers infuse technology into their Thinking Classrooms.

TeacherMade does more than convert PDFs into online activities. Teachers use TeacherMade to promote critical thinking skills. You can incorporate the Thinking Classroom practices with TeacherMade:

Every TeacherMade assignment is a non-permanent surface. Students can complete assignments again and again until they have reached mastery.
Create a culture of practice rather than homework and worksheets. With TeacherMade, you can choose to grade or not grade assignments. Students can complete practice as many times as they need.
TeacherMade supports asynchronous learning so that students can learn at their own pace.
Students are more involved with formative assessment when they receive instant feedback via auto-grading.
You can leave feedback, hints, and notes so that students fully understand their assessment results.

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How To Promote Critical Thinking In Your Classroom

Promoting Thinking

November 25, 2006, by The Critical Thinking Co. Staff

Modeling of critical thinking skills by instructors is crucial for teaching critical thinking successfully. By making your own thought processes explicit in class - explaining your reasoning, evaluating evidence for a claim, probing the credibility of a source, or even describing what has puzzled or confused you - you provide a powerful example to students, particularly if you invite them to join in; e.g., "Can you see where we're headed with this?" "I can't think of other explanations; can you?" "This idea/principle struck me as difficult or confusing at first, but here's how I figured it out." You can encourage students to emulate this by using them in demonstrations, asking them to "think out loud" in order for classmates to observe how they reason through a problem.

Develop the habit of asking questions that require students to think critically, and tell students that you really expect them to give answers! In particular, Socratic questioning encourages students to develop and clarify their thinking: e.g., "Would your answer hold in all cases?" "How would you respond to a counter-example or counter-argument?" "Explain how you arrived at that answer?"

This is another skill that students can learn from your example, and can use in working with each other. Providing regular opportunities for pair or small group discussions after major points or demonstrations during lectures is also important: this allows students to process the new material, connect it to previously learned topics, and practice asking questions that promote further critical thinking. Obviously, conveying genuine respect for student input is essential. Communicating the message that you value and support student contributions and efforts to think critically increases confidence, and motivates students to continue building their thinking skills. An essential component of this process is the creation of a climate where students feel comfortable with exploring the process of reasoning through a problem without being "punished" for getting the wrong answer.

Researchers have found consistently that interaction among students, in the form of well-structured group discussions plays a central role in stimulating critical thinking. Discussing course material and its applications allows students to formulate and test hypotheses, practice asking thought-provoking questions, hear other perspectives, analyze claims, evaluate evidence, and explain and justify their reasoning. As they become more sophisticated and fluent in thinking critically, students can observe and critique each others' reasoning skills.

Teaching Problem-Solving Skills

Many instructors design opportunities for students to solve “problems”. But are their students solving true problems or merely participating in practice exercises? The former stresses critical thinking and decision making skills whereas the latter requires only the application of previously learned procedures.

Problem solving is often broadly defined as "the ability to understand the environment, identify complex problems, review related information to develop, evaluate strategies and implement solutions to build the desired outcome" (Fissore, C. et al, 2021). True problem solving is the process of applying a method – not known in advance – to a problem that is subject to a specific set of conditions and that the problem solver has not seen before, in order to obtain a satisfactory solution.

Below you will find some basic principles for teaching problem solving and one model to implement in your classroom teaching.

Principles for teaching problem solving

Model a useful problem-solving method . Problem solving can be difficult and sometimes tedious. Show students how to be patient and persistent, and how to follow a structured method, such as Woods’ model described below. Articulate your method as you use it so students see the connections.
Teach within a specific context . Teach problem-solving skills in the context in which they will be used by students (e.g., mole fraction calculations in a chemistry course). Use real-life problems in explanations, examples, and exams. Do not teach problem solving as an independent, abstract skill.
Help students understand the problem . In order to solve problems, students need to define the end goal. This step is crucial to successful learning of problem-solving skills. If you succeed at helping students answer the questions “what?” and “why?”, finding the answer to “how?” will be easier.
Take enough time . When planning a lecture/tutorial, budget enough time for: understanding the problem and defining the goal (both individually and as a class); dealing with questions from you and your students; making, finding, and fixing mistakes; and solving entire problems in a single session.
Ask questions and make suggestions . Ask students to predict “what would happen if …” or explain why something happened. This will help them to develop analytical and deductive thinking skills. Also, ask questions and make suggestions about strategies to encourage students to reflect on the problem-solving strategies that they use.
Link errors to misconceptions . Use errors as evidence of misconceptions, not carelessness or random guessing. Make an effort to isolate the misconception and correct it, then teach students to do this by themselves. We can all learn from mistakes.

Woods’ problem-solving model

Define the problem.

The system . Have students identify the system under study (e.g., a metal bridge subject to certain forces) by interpreting the information provided in the problem statement. Drawing a diagram is a great way to do this.
Known(s) and concepts . List what is known about the problem, and identify the knowledge needed to understand (and eventually) solve it.
Unknown(s) . Once you have a list of knowns, identifying the unknown(s) becomes simpler. One unknown is generally the answer to the problem, but there may be other unknowns. Be sure that students understand what they are expected to find.
Units and symbols . One key aspect in problem solving is teaching students how to select, interpret, and use units and symbols. Emphasize the use of units whenever applicable. Develop a habit of using appropriate units and symbols yourself at all times.
Constraints . All problems have some stated or implied constraints. Teach students to look for the words "only", "must", "neglect", or "assume" to help identify the constraints.
Criteria for success . Help students consider, from the beginning, what a logical type of answer would be. What characteristics will it possess? For example, a quantitative problem will require an answer in some form of numerical units (e.g., $/kg product, square cm, etc.) while an optimization problem requires an answer in the form of either a numerical maximum or minimum.

Think about it

“Let it simmer”. Use this stage to ponder the problem. Ideally, students will develop a mental image of the problem at hand during this stage.
Identify specific pieces of knowledge . Students need to determine by themselves the required background knowledge from illustrations, examples and problems covered in the course.
Collect information . Encourage students to collect pertinent information such as conversion factors, constants, and tables needed to solve the problem.

Plan a solution

Consider possible strategies . Often, the type of solution will be determined by the type of problem. Some common problem-solving strategies are: compute; simplify; use an equation; make a model, diagram, table, or chart; or work backwards.
Choose the best strategy . Help students to choose the best strategy by reminding them again what they are required to find or calculate.

Carry out the plan

Be patient . Most problems are not solved quickly or on the first attempt. In other cases, executing the solution may be the easiest step.
Be persistent . If a plan does not work immediately, do not let students get discouraged. Encourage them to try a different strategy and keep trying.

Encourage students to reflect. Once a solution has been reached, students should ask themselves the following questions:

Does the answer make sense?
Does it fit with the criteria established in step 1?
Did I answer the question(s)?
What did I learn by doing this?
Could I have done the problem another way?

If you would like support applying these tips to your own teaching, CTE staff members are here to help. View the CTE Support page to find the most relevant staff member to contact.

Fissore, C., Marchisio, M., Roman, F., & Sacchet, M. (2021). Development of problem solving skills with Maple in higher education. In: Corless, R.M., Gerhard, J., Kotsireas, I.S. (eds) Maple in Mathematics Education and Research. MC 2020. Communications in Computer and Information Science, vol 1414. Springer, Cham. https://doi.org/10.1007/978-3-030-81698-8_15
Foshay, R., & Kirkley, J. (1998). Principles for Teaching Problem Solving. TRO Learning Inc., Edina MN. (PDF) Principles for Teaching Problem Solving (researchgate.net)
Hayes, J.R. (1989). The Complete Problem Solver. 2nd Edition. Hillsdale, NJ: Lawrence Erlbaum Associates.
Woods, D.R., Wright, J.D., Hoffman, T.W., Swartman, R.K., Doig, I.D. (1975). Teaching Problem solving Skills.
Engineering Education. Vol 1, No. 1. p. 238. Washington, DC: The American Society for Engineering Education.

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Building Thinking Classrooms: Conditions for Problem-Solving

First Online: 30 April 2016

Cite this chapter

Peter Liljedahl 6

Part of the book series: Research in Mathematics Education ((RME))

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In this chapter, I first introduce the notion of a thinking classroom and then present the results of over 10 years of research done on the development and maintenance of thinking classrooms. Using a narrative style, I tell the story of how a series of failed experiences in promoting problem-solving in the classroom led first to the notion of a thinking classroom and then to a research project designed to find ways to help teachers build such a classroom. Results indicate that there are a number of relatively easy-to-implement teaching practices that can bypass the normative behaviours of almost any classroom and begin the process of developing a thinking classroom.

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At the time, I was only informed by Mason ( 2002 ). Since then, I have been informed by an increasing body of literature on noticing (Fernandez, Llinares, & Valls, 2012 ; Jacobs, Lamb, & Philipp, 2010 ; Mason, 2011 ; Sherin, Jacobs, & Philipp, 2011 ; van Es, 2011 ).

Levelling (Schoenfeld, 1985 ) is a term given to the act of closing of, or interrupting, students’ work on tasks for the purposes of bringing the whole of the class (usually) up to certain level of understanding. It is most commonly seen when a teacher ends students work on a task by showing how to solve the task.

This research is now informed also by Norton and McCloskey ( 2008 ) and Anderson and Shattuck ( 2012 ).

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Liljedahl, P. (2016). Building Thinking Classrooms: Conditions for Problem-Solving. In: Felmer, P., Pehkonen, E., Kilpatrick, J. (eds) Posing and Solving Mathematical Problems. Research in Mathematics Education. Springer, Cham. https://doi.org/10.1007/978-3-319-28023-3_21

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5 Ways to Encourage Problem-Solving in your Classroom

A blog from osiris educational.

Osiris Admin
August 25, 2021

On average a teacher spends 86% of the time talking during a lesson. We are not giving our students the chance or the time to identify, solve and make their own mistakes.

How can we ensure they are learning the skills they need most without this vital part of the process?

Problem-solving skills are a necessary part of life and we as educators need to make sure students are prepped and ready to take on any issues they may be faced with.

The ability to identify, analyse and work out a solution is a valuable skill that is not only useful in the classroom, but also outside of school time. Implementing such practices into your classroom plan will help improve cognitive and social development. Once equipped with the tools they need to address and solve problems, students begin to take more control of their learning experience.

Here are 5 ways you can support problem-solving in your classroom:

1. Problem Solve as a Group

Have your students think aloud in a group setting. This allows for critical analysis and the chance to bounce solutions off each other. Introduce a two-column system whereby, the first column shows their idea to solve the issue and the second is the reasoning behind the idea. This helps students think about their own problem-solving skills and promotes cooperation whilst creating a solution.

2. Explain and Encourage

Explain the problem and encourage your students to think about why the task is important. Why is the way they came to a solution more important than the solution itself? Explain what skills they are gaining, why those skills will help and how a step-by-step process is better than a quick answer.

3. Time and Patience

Our basic nature means we want answers quick and fast without doing the work. Your students will want to race to the finish line with the quickest thought. We must show them that time and patience improve problem-solving and provides us with a clearer answer. Reminding your students that it is not a competition and not a race to finish first is essential.

4. Ask Questions and Reflect

Get your classroom thinking. Ask questions throughout the problem-solving task. Give them a chance to reflect. Once they have come to a solution, ask your students these questions:

Why did you choose that method?
Does this solve your problem the most efficient way?
What did you learn by solving this problem?
Could you have done this a different way?

5. Let them Learn

The hardest part. Hands off, let them work. As educators, we are eager to help, give answers and make sure our students are doing it the right way. To allow for success in problem-solving, we must allow them to make mistakes and work it out for themselves. Upon reflection, of course, make suggestions. Show them how you would do it, but these skills must be developed independently. After all, they won’t have you to guide them forever!

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11 Activities That Promote Critical Thinking In The Class

52 Critical Thinking Flashcards for Problem Solving

Critical thinking activities encourage individuals to analyze, evaluate, and synthesize information to develop informed opinions and make reasoned decisions. Engaging in such exercises cultivates intellectual agility, fostering a deeper understanding of complex issues and honing problem-solving skills for navigating an increasingly intricate world. Through critical thinking, individuals empower themselves to challenge assumptions, uncover biases, and constructively contribute to discourse, thereby enriching both personal growth and societal progress.

Critical thinking serves as the cornerstone of effective problem-solving, enabling individuals to dissect challenges, explore diverse perspectives, and devise innovative solutions grounded in logic and evidence. For engaging problem solving activities, read our article problem solving activities that enhance student’s interest.

What is Critical Thinking?

Critical thinking is a 21st-century skill that enables a person to think rationally and logically in order to reach a plausible conclusion. A critical thinker assesses facts and figures and data objectively and determines what to believe and what not to believe. Critical thinking skills empower a person to decipher complex problems and make impartial and better decisions based on effective information.

Importance of Acquiring Critical Thinking Skills

Acquiring critical thinking skills was never as valuable as it is today because of the prevalence of the modern knowledge economy. Today, information and technology are the driving forces behind the global economy. To keep pace with ever-changing technology and new inventions, one has to be flexible enough to embrace changes swiftly.

Read our article: How to Foster Critical Thinking Skills in Students? Creative Strategies and Real-World Examples

Today critical thinking skills are one of the most sought-after skills by the companies. In fact, critical thinking skills are paramount not only for active learning and academic achievement but also for the professional career of the students. The lack of critical thinking skills catalyzes memorization of the topics without a deeper insight, egocentrism, closed-mindedness, reduced student interest in the classroom and not being able to make timely and better decisions.

Benefits of Critical Thinking Skills in Education

Certain strategies are more eloquent than others in teaching students how to think critically. Encouraging critical thinking in the class is indispensable for the learning and growth of the students. In this way, we can raise a generation of innovators and thinkers rather than followers. Some of the benefits offered by thinking critically in the classroom are given below:

It allows a student to decipher problems and think through the situations in a disciplined and systematic manner
Through a critical thinking ability, a student can comprehend the logical correlation between distinct ideas
The student is able to rethink and re-justify his beliefs and ideas based on facts and figures
Critical thinking skills make the students curious about things around them
A student who is a critical thinker is creative and always strives to come up with out of the box solutions to intricate problems
Critical thinking skills assist in the enhanced student learning experience in the classroom and prepares the students for lifelong learning and success
The critical thinking process is the foundation of new discoveries and inventions in the world of science and technology
The ability to think critically allows the students to think intellectually and enhances their presentation skills, hence they can convey their ideas and thoughts in a logical and convincing manner
Critical thinking skills make students a terrific communicator because they have logical reasons behind their ideas

Critical Thinking Lessons and Activities

11 Activities that Promote Critical Thinking in the Class

We have compiled a list of 11 activities that will facilitate you to promote critical thinking abilities in the students. We have also covered problem solving activities that enhance student’s interest in our another article. Click here to read it.

1. Worst Case Scenario

Divide students into teams and introduce each team with a hypothetical challenging scenario. Allocate minimum resources and time to each team and ask them to reach a viable conclusion using those resources. The scenarios can include situations like stranded on an island or stuck in a forest. Students will come up with creative solutions to come out from the imaginary problematic situation they are encountering. Besides encouraging students to think critically, this activity will enhance teamwork, communication and problem-solving skills of the students.

Read our article: 10 Innovative Strategies for Promoting Critical Thinking in the Classroom

2. If You Build It

It is a very flexible game that allows students to think creatively. To start this activity, divide students into groups. Give each group a limited amount of resources such as pipe cleaners, blocks, and marshmallows etc. Every group is supposed to use these resources and construct a certain item such as building, tower or a bridge in a limited time. You can use a variety of materials in the classroom to challenge the students. This activity is helpful in promoting teamwork and creative skills among the students.

It is also one of the classics which can be used in the classroom to encourage critical thinking. Print pictures of objects, animals or concepts and start by telling a unique story about the printed picture. The next student is supposed to continue the story and pass the picture to the other student and so on.

4. Keeping it Real

In this activity, you can ask students to identify a real-world problem in their schools, community or city. After the problem is recognized, students should work in teams to come up with the best possible outcome of that problem.

5. Save the Egg

Make groups of three or four in the class. Ask them to drop an egg from a certain height and think of creative ideas to save the egg from breaking. Students can come up with diverse ideas to conserve the egg like a soft-landing material or any other device. Remember that this activity can get chaotic, so select the area in the school that can be cleaned easily afterward and where there are no chances of damaging the school property.

6. Start a Debate

In this activity, the teacher can act as a facilitator and spark an interesting conversation in the class on any given topic. Give a small introductory speech on an open-ended topic. The topic can be related to current affairs, technological development or a new discovery in the field of science. Encourage students to participate in the debate by expressing their views and ideas on the topic. Conclude the debate with a viable solution or fresh ideas generated during the activity through brainstorming.

7. Create and Invent

This project-based learning activity is best for teaching in the engineering class. Divide students into groups. Present a problem to the students and ask them to build a model or simulate a product using computer animations or graphics that will solve the problem. After students are done with building models, each group is supposed to explain their proposed product to the rest of the class. The primary objective of this activity is to promote creative thinking and problem-solving skills among the students.

8. Select from Alternatives

This activity can be used in computer science, engineering or any of the STEM (Science, Technology, Engineering, Mathematics) classes. Introduce a variety of alternatives such as different formulas for solving the same problem, different computer codes, product designs or distinct explanations of the same topic.

Form groups in the class and ask them to select the best alternative. Each group will then explain its chosen alternative to the rest of the class with reasonable justification of its preference. During the process, the rest of the class can participate by asking questions from the group. This activity is very helpful in nurturing logical thinking and analytical skills among the students.

9. Reading and Critiquing

Present an article from a journal related to any topic that you are teaching. Ask the students to read the article critically and evaluate strengths and weaknesses in the article. Students can write about what they think about the article, any misleading statement or biases of the author and critique it by using their own judgments.

In this way, students can challenge the fallacies and rationality of judgments in the article. Hence, they can use their own thinking to come up with novel ideas pertaining to the topic.

10. Think Pair Share

In this activity, students will come up with their own questions. Make pairs or groups in the class and ask the students to discuss the questions together. The activity will be useful if the teacher gives students a topic on which the question should be based.

For example, if the teacher is teaching biology, the questions of the students can be based on reverse osmosis, human heart, respiratory system and so on. This activity drives student engagement and supports higher-order thinking skills among students.

11. Big Paper – Silent Conversation

Silence is a great way to slow down thinking and promote deep reflection on any subject. Present a driving question to the students and divide them into groups. The students will discuss the question with their teammates and brainstorm their ideas on a big paper. After reflection and discussion, students can write their findings in silence. This is a great learning activity for students who are introverts and love to ruminate silently rather than thinking aloud.

Read our next article: 10 Innovative Strategies for Promoting Critical Thinking in the Classroom

Strategies to Increase Critical Thinking Skills in students

Matthew Joseph October 2, 2019 Blog , Engage Better , Lesson Plan Better , Personalize Student Learning Better

In This Post:

The importance of helping students increase critical thinking skills.
Ways to promote the essential skills needed to analyze and evaluate.
Strategies to incorporate critical thinking into your instruction.

We ask our teachers to be “future-ready” or say that we are teaching “for jobs that don’t exist yet.” These are powerful statements. At the same time, they give teachers the impression that we have to drastically change what we are doing .

So how do we plan education for an unknown job market or unknown needs?

My answer: We can’t predict the jobs, but whatever they are, students will need to think critically to do them. So, our job is to teach our students HOW to think, not WHAT to think.

Helping Students Become Critical Thinkers

My answer is rooted in the call to empower our students to be critical thinkers. I believe that to be critical thinkers, educators need to provide students with the strategies they need. And we need to ask more than just surface-level questions.

Questions to students must motivate them to dig up background knowledge. They should inspire them to make connections to real-world scenarios. These make the learning more memorable and meaningful.

Critical thinking is a general term. I believe this term means that students effectively identify, analyze, and evaluate content or skills. In this process, they (the students) will discover and present convincing reasons in support of their answers or thinking.

You can look up critical thinking and get many definitions like this one from Wikipedia: “ Critical thinking consists of a mental process of analyzing or evaluating information, particularly statements or propositions that people have offered as true. ”

Essential Skills for Critical Thinking

In my current role as director of curriculum and instruction, I work to promote the use of 21st-century tools and, more importantly, thinking skills. Some essential skills that are the basis for critical thinking are:

Communication and Information skills
Thinking and Problem-Solving skills
Interpersonal and Self- Directional skills
Collaboration skills

These four bullets are skills students are going to need in any field and in all levels of education. Hence my answer to the question. We need to teach our students to think critically and for themselves.

One of the goals of education is to prepare students to learn through discovery . Providing opportunities to practice being critical thinkers will assist students in analyzing others’ thinking and examining the logic of others.

Understanding others is an essential skill in collaboration and in everyday life. Critical thinking will allow students to do more than just memorize knowledge.

Ask Questions

So how do we do this? One recommendation is for educators to work in-depth questioning strategies into a lesson launch.

Ask thoughtful questions to allow for answers with sound reasoning. Then, word conversations and communication to shape students’ thinking. Quick answers often result in very few words and no eye contact, which are skills we don’t want to promote.

When you are asking students questions and they provide a solution, try some of these to promote further thinking:

Could you elaborate further on that point?
Will you express that point in another way?
Can you give me an illustration?
Would you give me an example?
Will you you provide more details?
Could you be more specific?
Do we need to consider another point of view?
Is there another way to look at this question?

Utilizing critical thinking skills could be seen as a change in the paradigm of teaching and learning. Engagement in education will enhance the collaboration among teachers and students. It will also provide a way for students to succeed even if the school system had to start over.

[scroll down to keep reading]

Promoting critical thinking into all aspects of instruction.

Engagement, application, and collaboration are skills that withstand the test of time. I also promote the integration of critical thinking into every aspect of instruction.

In my experience, I’ve found a few ways to make this happen.

Begin lessons/units with a probing question: It shouldn’t be a question you can answer with a ‘yes’ or a ‘no.’ These questions should inspire discovery learning and problem-solving.

Encourage Creativity: I have seen teachers prepare projects before they give it to their students many times. For example, designing snowmen or other “creative” projects. By doing the design work or by cutting all the circles out beforehand, it removes creativity options.

It may help the classroom run more smoothly if every child’s material is already cut out, but then every student’s project looks the same. Students don’t have to think on their own or problem solve.

Not having everything “glue ready” in advance is a good thing. Instead, give students all the supplies needed to create a snowman, and let them do it on their own.

Giving independence will allow students to become critical thinkers because they will have to create their own product with the supplies you give them. This might be an elementary example, but it’s one we can relate to any grade level or project.

Try not to jump to help too fast – let the students work through a productive struggle .

Build in opportunities for students to find connections in learning. Encouraging students to make connections to a real-life situation and identify patterns is a great way to practice their critical thinking skills. The use of real-world scenarios will increase rigor, relevance, and critical thinking.

A few other techniques to encourage critical thinking are:

Use analogies
Promote interaction among students
Ask open-ended questions
Allow reflection time
Use real-life problems
Allow for thinking practice

Critical thinking prepares students to think for themselves for the rest of their lives. I also believe critical thinkers are less likely to go along with the crowd because they think for themselves.

About Matthew X. Joseph, Ed.D.

Dr. Matthew X. Joseph has been a school and district leader in many capacities in public education over his 25 years in the field. Experiences such as the Director of Digital Learning and Innovation in Milford Public Schools (MA), elementary school principal in Natick, MA and Attleboro, MA, classroom teacher, and district professional development specialist have provided Matt incredible insights on how to best support teaching and learning. This experience has led to nationally publishing articles and opportunities to speak at multiple state and national events. He is the author of Power of Us: Creating Collaborative Schools and co-author of Modern Mentoring , Reimagining Teacher Mentorship (Due out, fall 2019). His master’s degree is in special education and his Ed.D. in Educational Leadership from Boston College.

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3 steps to creative problem solving in the classroom

Teaching Strategies

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Bringing creativity into the classroom came naturally to Mark Gura. He began his career as a visual arts teacher in East Harlem, and when his small school asked him to teach other topics like English and social studies, it made sense to integrate some of his artistic skills into his lessons.

“Running a creative classroom was all about the culture I established,” Gura says. “I was bringing the students into another way of being. Not of thinking, but of being.”

To do that requires restructuring “habits of mind,” as Gura puts it. For example, many people think of creativity as a solo endeavor – the artist or writer who paints or writes in solitude. But creativity doesn’t happen in a bubble. Often it’s the result of team collaboration with a lot of brainstorming and bouncing ideas off each other.

How can educators best build a creative culture in their classroom? It begins with establishing a creative space where students can share their work. Gura is a fan of blogs, where students can post essays, videos or visual art projects and get real-time feedback.

Educators can also encourage students to come up with multiple solutions to specific situations. Too often, Gura says, students get caught up with finding the single correct answer to a problem. Instead, focus on finding multiple outcomes. Here’s how:

Develop a strategy. This involves researching the problem and its history to best understand it and then analyzing how others approached the problem and solved it. Look for mistakes made along the way and the gaps left to be filled.
Create a prototype, test or draft. Once students truly understand the problem, they are ready to solve it. This is where the creative community truly comes into play. Through collaboration, more minds are working on prototype solutions. Not only can students tap into their peers’ ideas, the feedback turns the classroom into a thought incubator where ideas are nurtured and grow.
Find an audience. Creative communities need a support system, someone outside of the creative team who can bring an unbiased perspective to the problem and solution. This can be done by soliciting feedback through blog posts, in a closed digital community or during classroom presentations. The idea is to use the audience to help refine the prototype or draft.

In creative classrooms, Gura says, the finished product isn’t the most important outcome. It’s the process of getting to a solution and then expanding it in new directions.

“That’s a huge shift in the habits of mind within the classroom,” he adds. “It’s ongoing, with students relying on the community for support.”

Discover ready-to-implement activities for developing student creativity in your school or classroom with Gura’s new book, Make, Learn Succeed: Building a Culture of Creativity in Your School.

artificial intelligence

Why Schools Need to Change Purpose and Problem-Solving: Developing Leaders in the Classroom

Taiwo A. Togun (he, him, his) Faculty, Pierrepont School, and Co-Founder & Executive Director, InclusionBridge, Inc. in Connecticut

Today’s learners face an uncertain present and a rapidly changing future that demand far different skills and knowledge than were needed in the 20th century. We also know so much more about enabling deep, powerful learning than we ever did before. Our collective future depends on how well young people prepare for the challenges and opportunities of 21st-century life.

As educators transform learning in their classrooms, they can develop their students ’ talent and their own leadership while also making a difference for their community.

“Purpose is a stable and generalized intention to accomplish something that is at once meaningful to the self and consequential to the world beyond the self” –Bill Damon, Professor of Education, Stanford University

As an educator, my purpose is to nurture and develop young talents. While I have been teaching for over a decade, I only articulated my purpose as an educator last year during my master’s program in technology leadership while learning to integrate technology, strategy, and leadership. Coincidentally, I became a Project Invent fellow at the same time, which only served to embolden my sense of purpose. Clarity of purpose is a vital leadership quality that shapes my experience and something I believe ought to begin every teacher’s leadership journey. While one’s articulation of purpose may change over time, there’s something quite powerful and differently effective about writing down and reading out loud your purpose statement. In the following reflection, my goal is to share how I approach my development as an educator and a leader as one and the same and how my experience with Project Invent’s design thinking curriculum represents a continuing education in leadership.

Developing a Leadership Identity

As I work toward establishing my leadership identity and persona as an educator, I find myself reflecting on Sun Tzu’s Art Of War in which he described “ Leadership [as] a matter of intelligence, trustworthiness, humaneness, courage, and discipline. ” Additional discourses from the likes of Thomas Carlyle , Tolstoy , and Plato have all helped me arrive at an understanding of leadership as a function of nature, nurture, and situation . In addition to clarity of purpose, other leadership qualities must be deliberately nurtured through training and cultivated through practicing acts of leadership. I believe an effective leader empowers others and recognizes situations when the act of leadership is, in fact, letting others lead. This summarizes the core takeaway of my “teacher as a leader” philosophy.

In 2021, I applied to Project Invent’s educator fellowship , hoping to reinforce my leadership identity as an educator. Project Invent is a nonprofit organization that trains educators in six key teacher practices, each aimed at empowering students with the mindsets to become fearless, compassionate, and creative problem solvers. As a Project Invent Fellow, I have made significant progress in mastering these six teacher practices:

Make failure okay
Push to the next level
Be a co-learner
Let students take the wheel
Leave room for exploration
Challenge assumptions

Courtesy of Project Invent

Leadership in Practice

Each of these teacher practices can occur independently but are often interrelated. Deliberately committing to one can undoubtedly lead to others. For example, being comfortable with being a co-learner allows space for leaving room for exploration of alternatives. Openness to the possibility of new alternatives begets making failure okay and also encourages letting students take the wheel and drive the process, while the teacher-leader nudges them to push to the next level. Of course, the order of these is not fixed.

I teach computer science at Pierrepont School in Westport, Connecticut. My Project Invent student teams come from two classes of juniors and seniors, who originally signed up for an Applied Data Science course. We began our journey in the second semester in January, after which the students were informed that their course name had changed from “Applied Data Science” to “Essential Skills of the Emerging Economy” which has two parts: “Critical Reasoning & Storytelling with Data” and “Human-centered Problem-solving.” These are the only details my brave students had to work with. Needless to say, students had to be open-minded about how the journey would shape up. After all, it is not the first time that I would modify course requirements to marry interests and new opportunities that would benefit my students. I enjoy such flexibility and reasonable autonomy at my school; I also enjoy the flexibility and reasonable autonomy of learning as I teach. I am comfortable admitting to my students that I have absolutely no idea how to solve a challenge that I assign them, but assure them we can figure it out together… and we always do.

In January, the challenge was dauntingly ambiguous: We were going to invent a new technology intended to positively impact members of our community. Given their awareness of how little I knew about what we might need, or how to invent anything for that matter, students had to buy into taking a journey with an uncertain destination together. My job as a co-learner was to make sure to emphasize that it was all about the journey, the lessons, and the fun we have; and not necessarily the end. The humility and willingness to be a co-learner with students in the driver's seat have served me very well throughout my journey as a teacher, and I can not begin to describe the gratification of learning with and from students and seeing them rise to the challenge. This time, however, we had access to a community of resources, fellows, and mentors through the extended Project Invent team, who made it even more reassuring despite the many unknowns. From the onset of our journey, my students demonstrated creative confidence and trust in one another (most of the time) and our system as a class. Together as a team, we were ready and excited for the journey.

“Coming into this class with a limited computer science background, I was a little intimidated to embark on a project that had the potential to create such a big and meaningful improvement in our community. However, as I grew more comfortable with my team, my fears eased. I was able to develop from a quiet listener to a confident doer, not only for the duration of this project but also in my longer-term data science pursuits.” –Alexis Bienstock, Pierrepont School Junior

Project Invent as Context for Leadership Development

Human-centeredness brings a new dimension to problem-solving. It helps to establish and define a worthy purpose. My students and I began our journey on our Project Invent experience by getting to know our “client” Roderick Sewell , a Paralympic athlete and swimmer, as a person—what he enjoys doing, how he got to become a serious athlete, and what his goals and aspirations are. We focused on his abilities, accomplishments, and strengths. This set the stage for helping us—students and teachers alike—cultivate mindsets of empathy and curiosity. It is this empathic curiosity that would eventually lead to two Project Invent teams of ambitious students, who set out to address Roderick’s expressed challenges of lower back pain and efficient switch from running to walking legs:

“Because there’s nothing to absorb the load except for my lower back…If there was a little more cushioning on the soles to absorb the impact, then everything would be even more doable.” “ I can’t really run with my walking leg. One question that I always have is if something happened, how fast would I be able to get up and get away? ” –Roderick Sewell

Team SNAILS, a team of one senior and five juniors, proposed and prototyped an invention they called Quick Switch Support Shoe (“QS-cubed”), a multifunctional prosthetic foot support with adjustable springs to minimize back pain and maximize run-walk efficiency for their community partner.

Team Pierrepont Innovators with three seniors and four juniors had the ambitious goal of completely redesigning Roderick’s prosthetic ankle with a dashpot or snubber mechanism and incorporating more effective shock-absorbing materials. They wrestled with disappointments as they came to terms with reality and time constraints, and the team eventually demonstrated resilience and agency as they made a pivot to capitalize on their research of Shock-absorbing materials. They developed a pitch to prosthetic companies which can incorporate their research insights to further possible impact.

The larger purpose of our 10-week journey into design thinking was our connection with Roderick’s expressed discomfort. This purpose shaped our introduction to need-finding, synthesizing and ideation, idea selection and prototyping, prototype refinement, and pitching. Students persevered through their fears, disagreements, and disappointments; they made it work because they did not think it was about them but rather about what they could contribute to support Roderick.

“Our community partner Roderick Sewell is the first bilateral above-the-knee amputee to finish the IRONMAN World Championship. As a serious athlete, he needs to feel his best to perform his best—and that’s our charge!” –Team Pierrepont Innovators

“Working on Project Invent provided me with an appreciation for Roderick Sewell and the time I spend with my classmates. The opportunity to learn Roderick’s story as we worked with him to develop solutions to his lower back pain proved to be the most rewarding part of the process.” –Hagen Feeney, Pierrepont School Senior

Understanding the Journey

“He who has a why to live for can bear almost any how.” –Friedrich Nietzsche

By default, as educators we teach process; learning to solve problems in several different ways is central to our training, and sometimes that dominates our lessons to students. The Project Invent experience helps educators and students alike to prioritize the “why” and “what” of our learning over the “how.” The Project Invent experience added the very essential element of “purpose” which helped my students and me push the boundaries of the typical project-based, creative problem-solving classroom experience. Indeed, such an experience only thrives in and helps to foster a culture of caring, purpose, learning, and enjoyment (all in the dimension of flexibility to respond to change)—the kind of culture espoused by our school, Pierrepont culture ! Through our experience with human-centered problem-solving, students and teachers alike have cultivated practices and mindsets that are necessary to become leaders.

Every Leader Needs a Community and a Support System

“Leadership without support is like trying to make bricks without enough straw. True leaders reinforce their ideas and plan with strategic partnerships, alliances, and supportive audiences.” –Reed Markham, Ph.D.

In addition to the Pierrepont culture that presented a fertile soil for the teacher practices and students’ mindsets we needed, the Project Invent community and support system were so important for us. I recall the confidence boost and reassurance from our first session with a volunteer expert, Valerie Peng, an engineer who builds robots for a living. Not only did my team get to soak invaluable information that was relevant for advancing our project, but we were also all inspired by the passion with which she shared her work with us. Similarly, I found renewed strength and motivation with each conversation with Project Invent staff members and other fellows. In our shared space as educator-leaders, my co-fellows and I were able to explore possible solutions to shared challenges like keeping students motivated through their fears and disappointments, navigating operational logistics and schedule challenges, etc. I am indeed grateful for such a community as it helps to know you are not alone.

Beyond the Classroom

The teacher as leader practices cultivated during my Project Invent experience has affected my work beyond Pierrepont. With clarity of purpose and the necessary focus on impact and human-centeredness, my data science consulting company has embarked on a renewed mission to diversify the data science workforce and bridge the gap to full and equal participation in the emerging digital economy through InclusionBridge . Indeed, the Project Invent experience provided a complementary lens for me to refine my purpose—my journey—of nurturing and developing young talents through problem-solving and meaningful learning experiences. I enjoy creating and facilitating opportunities to help students become fearless, compassionate young leaders.

Image at top is a slide from the student project presentation by Team SNAILS, Pierrepont School.

Taiwo A. Togun (he, him, his)

Faculty, pierrepont school, and co-founder & executive director, inclusionbridge, inc..

Taiwo is an educator, a data scientist, and a social entrepreneur who is passionate about nurturing and developing young talent. He is the architect and director of the Computer Science program and Innovation Lab at Pierrepont School , a private K-12 where he enjoys the challenge of making computer programming and problem-solving skills accessible to students at all levels. Dr. Togun is a visiting scientist at the Boykin Lab at the Department of Cognitive, Linguistic, and Psychological Sciences at Brown University, supporting research to elucidate perceptions of fairness in machine learning algorithms. With a Ph.D. in computational biology & bioinformatics from Yale and a master's in technology leadership from Brown, he combines data science, technology, strategy, and leadership as co-founder and executive director of InclusionBridge . Through InclusionBridge, Taiwo and his team are on a mission to increase diversity in the data science workforce through internships and training programs for underrepresented talent. Follow Taiwo on LinkedIn .

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Strategies for teaching metacognition in classrooms

Subscribe to the center for universal education bulletin, david owen and do david owen history and politics teacher - melbourne high school - victoria, australia alvin vista alvin vista former brookings expert @alvin_vista.

November 15, 2017

This is the third piece in a six-part blog series on teaching 21st century skills , including problem solving , metacognition , critical thinking , and collaboration , in classrooms.

Metacognition is thinking about thinking. It is an increasingly useful mechanism to enhance student learning, both for immediate outcomes and for helping students to understand their own learning processes. So metacognition is a broad concept that refers to the knowledge and thought processes regarding one’s own learning. Importantly, there is research evidence (e.g., Moely and colleagues, 1995 ; Schraw, 1998 ) that metacognition is a teachable skill that is central to other skills sets such as problem solving, decisionmaking, and critical thinking. Reflective thinking, as a component of metacognition, is the ability to reflect critically on learning experiences and processes in order to inform future progress.

David Owen, who teaches history and politics at Melbourne High School in Victoria, Australia, discusses a simple but effective approach to encourage student self-reflection:

I have rethought some of my classroom strategies this year. I teach at a secondary school which prides itself on its high level of student achievement, and I had always believed my students performed accordingly. They always ask for help before, during, and after class. Their varied queries could be superficial knowledge-based questions or more general questions about their progress, but I’d always read this habit as a sign that my students had an open mindset: they were inquisitive, cared about their learning, and charted their progress.

But having students asking a million questions of the teacher poses another challenge entirely, which can be framed: “Why aren’t students asking these questions of themselves?”

Recent shifts in pedagogy have emphasized the importance of encouraging students to figure out how to be independent, self-regulated learners. The teacher cannot be there to hold their hand beyond school. This demands that students reflect on their learning in meaningful ways. It also requires students be critical analysts of their own thinking in order to overcome complex or unexpected problems.

I’ve begun to highlight strategies which might better encourage this kind of metacognition. For younger adolescents, I’ve found that “Exit Tickets” are an opportunity for students to reflect on what they have accomplished and what they could improve on. Exit Tickets are a family of feedback tools that students complete for a few minutes at the end of each lesson. They prompt students to think about how and what they learn, as well as what challenges they are still facing.

“Traffic Lights” is a simple yet effective Exit Ticket which emphasizes three key factors:

When students encountered a challenge;
When students had thought differently about something; and
When students were learning well.

Over time I’ve found myself more interested in student responses to the Yellow Light, because it requires students to think about how they were thinking, rather than when (the emphasis of the Red and Green lights). The Yellow Light encourages reflective thinking as well as “thinking about thinking, or what is known as metacognition.” The possibilities for Exit Tickets are numerous and easily adaptable to the content and specific skills taught in any lesson.

Another example of reflective, self-directed learning which is suited to group work is setting a classroom rule that groups ask a question together , rather than individually. What this means is that rather than immediately ask the teacher for help, a student who has encountered a problem must consult with their group first. If the group cannot collectively find the solution, they can raise their hands simultaneously—a sign that the question has been fielded to the group already. There are various ways to modify this rule: highlighting with traffic-light colors, like in the Exit Ticket activity, is one such example.

For older students, setting a few rules before requesting aid from the teacher has seen their self-directed learning—and my feedback—improve markedly. I have emphasized that students seek specific feedback concerning their trial exams. I ask students to ensure they have highlighted and annotated their responses before seeing me. This approach shifts student thinking from the simplistic “submission to feedback” principle towards a more involved process, where students must consider what feedback they would want, what advice they would give themselves, and where they think they need to improve. This approach encourages the students to independently exercise control over their learning and progress, thereby making them more independent and self-directed learners.

Evidence supporting the impact of metacognition suggests that students applying metacognitive strategies to learning tasks outperform those who do not ( Mason, Boldrin & Ariasi, 2010 ; Dignath & Buettner, 2008 ). The classroom approaches that David Owen uses in his classroom demonstrates one way of developing parts of this important complex skill. Interestingly, although these skills are so important in our modern world, the approaches discussed here are practical, do not require 21st century technology or resources, and can be applied in almost any classroom setting.

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Problem Solving in the Classroom

Success Story

Last week during our class meetings, I noticed a disturbing habit developing among my students. Sometimes they don't want to switch seats and move away from their best friends, and sometimes they want to be the last one standing (when we do an activity that has us sit down after our turn). Then we talked about how this might make everyone else feel and how it might affect our class community. We agreed that this was a problem because it did not make everyone feel welcome. Finally, I asked them for suggestions to solve the problem.

We have been working on problem solving all year. I started by teaching my students that solutions always need to be related, respectful, reasonable, and helpful. This is a challenge for students who often think of punishments before solutions. As we started talking about possible solutions to this problem, the first few solutions were not surprisingly more like punishments, such as, having the culprits sit out of future greetings and activities until they were being kind, or skipping offenders in the circle. However, the more we talked, the more they began to consider ways to prevent the problem from even occurring. Eventually we settled on two possible preventative solutions:

1) they could come to the circle separately and choose a place to sit away from close friends so they wouldn't be tempted to resist moving.

2) we could make assigned seats around the circle so that no one would feel uncomfortable about moving if necessary.

At this point, I told the class I would consider both solutions. It seems that I've taught them well about how to solve problems fairly because immediately one student suggested that I let the class vote. It was hard to argue with her logic and truthfully both solutions were acceptable. So this morning we had a vote. I had the kids close their eyes and raise their hands. They voted (20-3) to have assigned seats. When they opened their eyes and I announced the winning solution they started fist pumping with excitement.

I couldn't help but smile. I could never have imagined such a positive reaction to the idea of assigned seats for class activities. In fact, I suspect that had I forced the idea of assigned seats on them as a "punishment" or consequence, I would have heard lots of complaints and frustration. Yet when they could appreciate the problem and come to the solution on their own, they were more than willing to accept the idea. We immediately created a chart with assigned circle seats and by the afternoon they were already reminding each other where they needed to sit. Love it! Sarah Werstuik, Washington, D.C.

Teach Students the 4 Problem-Solving Steps

Another way to solve problems in the classroom is to teach students the 4 Problem-Solving Steps.

Post a copy of the 4 Problem-Solving Steps where students can refer to it (maybe next to a "peace table").

Problem-Solving Steps

Do something else. (Find another game or activity.)
Leave long enough for a cooling-off period, then follow-up with the next steps.
Tell the other person how you feel. Let him or her know you don’t like what is happening.
Listen to what the other person says about how he or she feels and what he or she doesn’t like.
Share what you think you did to contribute to the problem.
Tell the other person what you are willing to do differently.
Work out a plan for sharing or taking turns.
Put it on the class meeting agenda. (This can also be a first choice and is not meant as a last resort.)
Talk it over with a parent, teacher, or friend.

After discussing these skills, have the children role-play the following hypothetical situations. Have them solve each of the situations four different ways (one for each of the steps).

Fighting over whose turn it is to use the tetherball.
Shoving in line.
Calling people bad names.
Fighting over whose turn it is to sit by the window in the car or bus.

Teachers can put the Four Problem-Solving Steps on a laminated poster for students to refer to. Some teachers require that children use these steps before they put a problem on the agenda. Other teachers prefer the class meeting process because it teaches other skills. Instead of making one better than the other (class meeting or one-on-one), let children choose which option they would prefer at the moment.

This tool and many others can be found in the Positive Discipline Teacher Tool Cards .

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Promoting Problem-solving Skills in Young Children

Roselia Ramirez : I'd like to welcome you to the Home Visiting webinar series. We are happy that you have joined us today. The topic for our session is focused on problem-solving and how home visitors can partner with parents to really support its development. Before we get started, we want to tell you a little bit about us and want to have you meet your hosts for today's session.

My name is Roselia Ramirez and I am a senior training and technical assistance specialist at the National Center on Early Childhood Development Teaching and Learning, or DTL for short. I'm happy to be joining you from my home state of Arizona, and I'm going to turn it over to my colleagues and have them introduce themselves. Hey Joyce.

Joyce Escorcia: I am Joyce Escorcia, and thanks everyone for choosing to spend your hour with us. I work alongside Roselia and Sarah at DTL as a senior T and T specialist. You may have seen me in the Coaching Corner webinars and some other places and spaces. Thanks for joining us. We're excited to dig into our topic today. Sarah, do you want to introduce yourself, and share a little bit about yourself?

Sarah Basler: I'm excited to join you all today; you might recognize me as one of the presenters of the Coaching Corner webinar series and my role and work tends to be around coaching and specifically using PBC to support practitioners and even supporting coaches in their PBC practice. I also have a background in pyramid model practices. I'm excited to be here today and talk with you all about problem-solving, which is one of my passions. Thanks so much for having me today.

Roselia: Thanks for joining us, Sarah. It's exciting to see you and to have you as our guest for today on this often-challenging topic for many home visitors as well as parents. Thank you again, and it's so nice to see you. We do probably have some new viewers joining us today. We were wondering if you could start by giving an overview of the Practice-Based Coaching model and then share with our viewers some of the benefits of coaching for a home visitor.

Sarah: Sure. A quick little recap for some of you, and an introduction for others, Practice-Based Coaching or PBC as we call it for short, is a coaching model that when used with fidelity can lead to positive outcomes for children and their families. PBC can be used with anyone, so you can, a coach can support teachers or support home visitors, family childcare providers, or even other coaches. We refer to those that are receiving the coaching as a coachee, to support them to use a set of effective practices. PBC is a content-ready model, which means that any set of practices can be the focus for the middle of the cycle, visual, and so whatever set of practices that you might want to be the focus of coaching can go in the middle there.

The coach and the coachee together identify some strengths and needs related to those effective practices that have been selected for coaching and together they write a goal and an action plan to support that coachee in their implementation of those goals. The coach and the coachee engage in focused observation. The coach will come in and observe the coachee using those effective practices selected in their action plan. Then they meet and reflect about what happened during the focused observation, and the coach will give some feedback, some supportive, and some constructive feedback.

All of these components of PBC fit within a collaborative partnership. PBC occurs in that context, and it's really about a coach and a coachee coming together to work together and support the implementation of those effective practices. When we think about what those benefits might be for a home visitor, a home visitor could share with their coach, challenges that they might be facing related to working with families and together, a coach and the home visitor could talk through maybe some possible solutions or strategies that the home visitor may want to try with the family or support the home visitor in learning a little bit more about a certain set of effective practices.

Sometimes it's really nice to have that support and a colleague to ask your questions and get some ideas. A coach can support a home visitor to grow their home visiting practices. A coach could support them not only around maybe effective practices to try with the, to support the family to use, but could support the home visitor in growing their home visiting practices themselves. Thinking about how to enhance those skills.

Roselia: Thanks, Sarah, I really like the whole notion. The first thing that kind of comes to my mind is this whole idea of having a thought partner. But before we go any further into this topic, and this discussion, if you're just joining the session, we would like to remind you to visit that teal color widget that's at the bottom of your screen. Here's where you can gain access to this participant's guide that you're seeing a little screenshot on your screen now. This resource is intended to be interactive and you're going to hear us reference it and then direct you there during the session for some opportunities for engagement as well as some reflection.

I also want to point out that on the first page of the participant's guide, you're going to find some icons and images that we have been using in our home webinar series, such as the focus on equity segment and this is represented by that little magnifying glass image. I also wanted to mention that not every one of our Home Visiting webinars will have each of the segments in each of the webinars, but just to give you an idea of what those are when you do see them. The other thing we want to do before we go any further is we want to review the learning objectives that we have established for this session.

We have identified and framed the session around two learning goals. First, by the end of the session, we anticipate that you'll be able to describe some essential components of problem-solving, and then second, that you will have some practical strategies and resources that are intended to not only strengthen but nurture problem-solving within that home environment. Now in your participant's guide, we have provided a space for you to reflect and to think about your own learning goals and what you would like to walk away with from this session. Think about that for a moment. What's something that maybe a question that you might have or a type of reflection, something that you would like to walk away with. Take a moment and then jot down your thoughts in your participant's guide.

Joyce: To frame the space that we're in today for our Home Visiting webinar series this year, we've been focusing in on topics that have an impact on social and emotional development. As many of you know, social-emotional development is one of the domains in the Head Start Early Learning and Outcomes Framework, or the ELOF . You can see we have it highlighted here on the slide. When we began the series this year in October, we focused in on the home environment, and then in December, we focused in on relationships. In our last webinar, we really focused in on emotional literacy.

If you missed these webinars, don't worry, you can catch it on Push Play, and you'll have information about that towards the end of our webinar today. For our time today, we're really excited; again, I'm super excited to have my cohost from the Coaching Corner webinar series. I'm excited to be here with Sarah to focus on problem-solving and the practical strategies that we're going to be talking about today. We're really going to be looking at how a home visitor can support and partner with families kind of introduce and nurture that skill within young children. That's really where we're going to be at today.

Again, we wanted to make that connection with the Pyramid Model. While we're not going to go deep into the pyramid, we do want to just make that connection today that the Pyramid Model is a framework of evidence-based practices for promoting young children's social-emotional development. The Pyramid Model builds upon a tiered public health approach by providing universal support to, universal supports for [inaudible]. Animations are going a little wonky on me today. Universal support to all children to promote wellness and then targeted services to those who need more support and then also intensive services for those that need them.

In this webinar, we're going to be focusing in on problem-solving, which is that tier two targeted kind of social-emotional support piece, which we know are essential and important to healthy social development. That's where we're going to be focusing in on today, with, we're thinking about the pyramid. If you want to know more about the pyramid, check out the National Center for Pyramid Model Innovations, or NCPMI . We have links to that within the resource, within your viewer's guide for today. Be sure and check that out as well. We are again super fortunate to have Sarah with us today. We just really want to draw on all of her experience that she's had out in the field and really sharing some of her insight on problem-solving. Sarah, I'm going to pass it over to you.

Sarah: Social competencies like self-regulation, empathy, perspective taking, and problem-solving skills are really foundational to that healthy social-emotional development, and this includes positive interactions like friendship and relationship skills between peers and siblings. Young children really need that support of adults in their lives to help them learn these skills so that they can develop healthy relationships among peers and find ways to really work through social conflicts. As home visitors, you can support this process by really supporting teaching and modeling with families how to help their children develop these skills earlier on.

It can start as young as infants and toddlers. Home visitors can support building these foundational problem-solving and relationship skills that most children can access with adult support and start to use independently as they start to, as they continue to develop these skills. Children, as they become more independent, they'll tend to run into situations in their environment that can lead to frustration or even some challenging behavior.

If parents are intentional and teach children these skills early on in their development, they can become pretty fluent in problem-solving. Then as they learn these skills, they can become more independent and successful with these skills. Their self-esteem will then, in turn, increase, and they will be likely to be able to cope with certain levels of frustration as a result and engage hopefully in less challenging behavior. When they feel confident in these social interactions and are able to problem solve successfully, then we're going to likely see less challenging behavior.

Roselia: Sarah, this is a good place to note that as you get to know your families, you may also discover that there might be some children who struggle, and they don't readily learn these skills through those foundational teaching strategies such as modeling or co-regulation. This might include children with disabilities or suspected delays. Establishing that strong relationship with the parent becomes even more important to get more familiar with and to be aware of the struggles so that you as a home visitor can then explore and use some of those more individualized practices to work on these skills when children need that extra support. We're going to talk some more about that throughout this webinar, but we just thought that would be really important to point that out.

Let's talk a bit more about why problem-solving is important in child development. We know that the earlier that children begin solving those problems, the more ready they are to deal with bigger challenges as they mature. We know that the home is a safe, it's a controlled environment, where parents can direct children as they develop and practice those problem-solving skills. By viewing problems as opportunities to grow, children begin to broaden their understanding while building that confidence that you were talking about.

We also know that when children feel overwhelmed or maybe hopeless, they often, they're not going to attempt to address a problem and that's where some of this challenging behavior for us adults may come up. When they have support, and then adults really support them with that clear formula and some steps for solving problems, they'll feel more confident in their ability to even give it a try. By introducing problem-solving skills at a young age, children learn to think in terms of manageable steps. Sarah, can you share with us how a home visitor might go about this process with families?

Sarah: There are some steps to problem-solving that home visitors can use and introduce to parents and there are some ways that you can support families to incorporate these steps as they encounter social conflict in the home or in socialization. The first is to support children in identifying the problem. This can be simply stating what the problem is out loud and it can make a big difference for children and that even includes infants and toddlers as well as preschool-age children who are feeling stuck. Parents can really think about how to do this in an age-appropriate way to support their child to state what the problem that they're encountering is, such as, your sister doesn't want to play with you, or I see you're having a hard time rolling over, or would you like a turn?

Once the problem has been identified, parents can help their child to think about what some solutions might be to solving their problems. Parents can help to brainstorm possible ways that they might solve that problem. As a home visitor, we can help parents understand that all solutions don't necessarily need to be a good idea, meaning that really just the idea of children coming up with these ideas or sharing some possible solutions. We want to support that process and allow children to share no matter how silly it may sound, and we can support them by offering suggestions to them. The goal is for parents to help their child explore options and the key is to help them do this with creativity and support them to find many different potential solutions because we know that there's not one right way to solve a problem and we want to support children to be able to think of multiple solutions.

Parents can even talk through and help their child identify what the pros and cons of each solution might be. Parents really play this critical role in helping their child identify potential positive and maybe negative consequences for each potential solution they've identified. Once the child has evaluated the possible pros and cons of each solution, the parent can encourage them to pick a solution and try it out and see what happens.

That's where even sometimes those silly solutions that they come up with, it's okay, let them try it out because if it doesn't work, you can support them to try out a different solution. And finally, the last step would be really analyzing or evaluating if it worked. Did this solution that you tried work? Was it, did it solve your problem? And if it doesn't work, you can always come up with a different solution and help them to brainstorm new ones.

Roselia: Thanks Sarah. I think that's a really great way to kind of break down that process and a great way for home visitors to support parents as they're kind of working through that. From your experience as a coach, and then just the various different learning settings that you had the opportunity to work in, why do you think problem-solving is so important?

Sarah: Problem-solving skills give children that independence that they really crave. It gives them agency in their own lives. Even though they may not be able to do this independently right away, when we give children the tools that they need to be able to do this successfully, they're able to navigate interactions with others and it helps to build social competence that they're going to carry with them for the rest of their lives. No matter what the learning environment is that you are in, social interactions are inevitable. They happen all the time. It's important that adults give children the tools that they need and support them to use those tools when they need them so that they become independent and confident in solving these problems when they arise.

Joyce: When Sarah was talking, I said I really love how you made that connection about the importance of parents supporting that, because I think it goes back to what we stated when we started. That about supporting children to become these confident, capable children really does kind of lead into being confident, capable adults who can kind of explore the world around them with all the skills that they need. I think that it just makes a case why this is so important. Because we know that solving problems really is about making choices. As young children develop their problem-solving skills, they build their confidence and we just know that you know, that having all of that, being able to solve problems, figuring things out, really makes them happier, more content, and just independent individuals. That's really what we want.We know when they tackle problems on their own or in a group, they become resilient and persistent. They learn how to look at challenges from a fresh perspective, and therefore, they're confident enough to take more calculated risks and problem-solving is so important in child development.

Again, because we know if we do it and we get it right when they're little, it really turns into this other thing when they become adults that they become confident and capable and are good with taking risk in all kinds of other different ways. Some of you may be wondering why you're here with us, wondering what skills do children need to be successful at problem solving? This is important, like I know it's important. What skills do they need in order to be able to do it well and in order for children to be successful at problem-solving and developing relationships there are a lot of prerequisite skills that are required and needed.

We're going to talk a little bit about that, but we want to open up the Q and A for you guys to say okay, what skills do you think are important for children? What do you think that they might need in order to problem solve? We're going to ask you to pop that into the Q and A, right there, just click on the Q and A widget and put your responses there. We're going to share some of those out. While you guys are kind of thinking and popping ideas into the Q and A, we want to ask Sarah and bring her into the conversation of, Sarah, can you share with participants what some of those, what you think some of those prerequisites could be?

Sarah: For prerequisite skills, as you mentioned Joyce, problem-solving is really complex and it's going to require that a child be able to do many different things at the same time. When we think about children three and up, what they might need to be successful at problem-solving, then you really need to be able to initiate and respond to others. That could be a verbal or a nonverbal interaction or response, and it would vary, of course, based on the child's age or ability. This might look like if a child wants a toy that another child has, it could look like holding out their hand to ask or asking for a turn. A response might look like the other child saying no, I don't want to give you a turn, or pulling the item back to say, I don't want to give you the toy. Children really need to be able to initiate and respond to be successful at problem solving.

Another thing that they need to be able to do is identify emotions in themselves and in others. The reason this is important is because have you ever tried to solve a problem when you're upset? It's really hard. You're not thinking clearly. It's just not going to work. Children need to be able to return themselves to that state of calm before they're able to come up with solutions to their problem, or even to recognize what their problem is. Another step is being able to calm themselves or having an adult support them to calm down.

The next skill might seem obvious, but children really need to be able to identify what the problem is. That could look like a child identifying hey, I've got two apples but there are three siblings here. And what, my problem is I've got two apples, and we don't have enough. Once they've identified the problem, children really need to be able to then come up with possible solutions to solve their problem. That could be that child identifying hey, if I split this apple, we all have some. Or it might be, I don't like apples, so you can have mine.

These skills that I just mentioned are really higher level for maybe preschool-age children, but a home visitor can also support families of infants and toddlers by setting the stage for problem solving. Making sure the environment really promotes interactions with others. Are there opportunities for that child or other children in the home to engage with one another? There usually are, even in routines that we don't think there are, you can build in possible opportunities. Pointing those out for the family, helping them think about what they might do or say and providing, helping support them to provide more opportunities throughout the day.

Another way that a family could support problem-solving in the environment is narrating or pointing out the intentions or what another child might be wanting or needing so that could sound like, “oh, I see Julia crawling towards you. It looks like she wants to play with your ball.” What this does is really builds awareness of the wants and needs and intentions of others. I think that's so important because often I know you've been around children, you know that sometimes it feels like a threat and when we can narrate what's going on, we can frame what's going on for the child so that then they approach it as in a different way.

Of course, it's important to share that if a coach is working with a home visitor to support families to use these practices, a coach can help a home visitor identify what those prerequisite skills are that might need to be taught to the child first, the family or the child to be successful. It's important to note that a coach can be an extra set of eyes. And that, some of the things that I mentioned are coming in on the chat, I'm seeing, or in the Q and A, some people are saying kids need to be able to share, kids need to be able to ask for what they need, kids need to be able to identify the problem, and so it looks like you guys are right in line with what we were talking about. Really having friendship skills is important. Thank you so much for your responses.

Joyce: I feel like folks have a lot of ideas to share about what it takes to problem solve. And again, thank you for all your responses; keep them coming in. We just talked about, there are a lot of things needed for children to be successful at problem-solving and we still see a lot of the responses here we see coming in in the chat. We have Kate and Catrina that talk about regulating emotions. We have Tom that talked about think about possible solutions and then also as adults think about how can we help kind of set them up with possible solutions. Thank you for putting all of those things in there. As you can see, there's a list there added to the list that is coming in the Q and A. All of those things all in mind, problem-solving steps that we talked about and how a home visitor might support the development of this process.

Sarah, just to pop in with a quick question here, when you were talking and explaining the, when you were explaining kind of the why. Like why because it kind of helps to take away that threat aspect of it. As a coach we do that with our coachee or home visitor and do you think that there's some importance or connection then as a home visitor having that knowledge than to be able to have that parallel process of sharing that information with a print of like this is why it's important to narrate kind of that parallel top piece. Do you think that that could also be helpful for a home visitor?

Sarah: Yes, absolutely. I think as adult learners, and when you're working with parents, working with adult learners, it's really important for them to know the why. Why are you telling me to narrate? Pairing the narration is important because it helps children feel less threatened by the other child and you share the intentions. Then it helps make it more, gives the parents the why. Why would I do this? And then they know that the possible impact that using that practice might have. It's really a parallel process. What you would, your coach would use with you, you might also use some of those strategies with the families that you would work with.

Joyce: Yeah, thank you for sharing that. I said it was just when you said that, that light bulb went off, like wow, that's important information to kind of share on both sides, so thank you for that.

Now we're going to just summarize some of those key ideas and practices for home visitors and how they can support some of those problem-solving skills. Again, a lot of things have been coming in through the Q and A. Number one is just to promote healthy relationships, that home visitors can support parents in how they engage with and offer opportunities for young children to work on relationship skills. Sharing and helping and cooperating and comforting and making suggestions about play, even celebrating each other, and creating developmentally appropriate opportunities for practicing those skills throughout the day.

Home visitors can support parents in creating opportunities within the home as well as exploring options where children can practice turn-taking and sharing. Maybe through a socialization activity. Particularly when you're thinking about when there's just one child in the home, parents may have a concern about their child not having opportunities to engage with other children, so that could be a great time to just kind of pause and think about the value they place on peer relationships and how they might be able to provide some of those opportunities for their child. Thinking about some of those being intentional and some might be planning some outdoor activities, some field trips, some going to the park, visiting with their cousins or whatever that aspect.

Just knowing that can also help with thinking about, like, 'Wow, every interaction could be a learning moment, an opportunity to kind of learn and grow these skills.' Thinking about teaching problem-solving steps that earlier we talked about - some steps that home visitors can work through with parents. When it comes to developing problem-solving skills, young children are learning to manage their emotions and behaviors through co-regulation. They're beginning to reason and understand simple consequences. Our role as a home visitor, we have that opportunity to work with parents and support the development of problem-solving.

Problem-solving development at this young age allows children to identify problems, brainstorm possible solutions, and then test those out, test out those appropriate solutions, and then analyze and think about, "Okay, so what kind of results did I get? Did I get what I wanted in the end?" Parents can support children to work through these steps and gain confidence in their ability to work through the problems that they encounter.

Another component would be teaching problem-solving in the moment. Problem-solving is hard work. It is hard work, but a 2-year-old solving problems is hard work for everyone involved sometimes. As home visitors, we have that unique opportunity of supporting this process. We want to build a parent's skill base and their confidence really to help their child use problem-solving steps in the moment. As home visitors can partner with parents to brainstorm ways they can anticipate those social conflicts before they happen. When a problem arises, the parent can anticipate or recognize problems before things can escalate and get out of hand and feel overwhelming or intervene as needed to work through those problem-solving steps that home visitors can support.

How parents individualize strategies they use to provide support, all these skills, really based on the learning kind of style and needs of their child. We know that some children may need the amount of language used to be modified; some children may need visual cues or gestures kind of paired with verbal language; some children may need specific feedback about consequences to really help them learn about the effect of their behavior on the environment really based on the individual needs of that family and the children as well.

Roselia: Thanks for sharing all that, Joyce. That's a lot of great information, and as you were saying all these things that we're doing to support parents or children rather — I think someone mentioned this earlier — about even as adults, problem-solving is difficult for us sometimes. To imagine for children that don't have the words and they're struggling with all these different emotions and wanting to stake their independence, it can really be a tough process.

As home visitors, we're in that unique position to really help support. Thanks for sharing all that. Throughout this webinar, we've really been discussing ways to foster problem-solving skills for all children. Today, in our focus on equity segment, we're going to use our equity lens to take a closer look and really lift up the value of equity in all learning environments as we work with diverse families in our communities.

As home visitors, it is safe to say that we are working with a diverse group of families, and we never want to make any assumptions. Let's reflect on this question: How can a home visitor be sure that they are being culturally responsive to a family's values related to relationships and problem-solving? Think about that because we know it's not a cookie-cutter approach and we know that there are cultures within cultures. It's important that we don't make any assumptions, and thinking about being culturally responsive, how can a home visitor ensure that that is happening?

We'd like for you to take some time and share some of your thoughts with us in the Q and A. While you're doing that, we do have a few suggestions that we would like for you to consider. First, we want to make sure that the skills that you're introducing are culturally relevant to the family that you're working with. It's important to really take the time and think back to the information that you've gathered as you've been developing a relationship with the family. You want to be sure that you're considering the values, beliefs, what's important to them, what's important that, the importance and the goals that they have for their children, and again, not making any assumptions and really asking these types of questions as you're moving through the process.

We also recommend that you take the time to gather input about social problems that the child may face at home or perhaps other settings that they're participating in. Then lastly, although we just mentioned this, we wanted to place an emphasis on the importance of gathering information about the family's values. As you're building those relationships, as you're observing the family, just really asking those questions, and not making assumptions from your perspective but from how the family states it. It's important to remember that problem-solving and how it is approached is not going to look the same for all families. Again, even if you have families that are from the same culture, what works for one family may not work for another. It's important for the suggestions and the strategies to be culturally responsive and respectful of a family's values. Sarah, folks are still entering their thoughts into the Q and A. Is there anything that you would like to add?

Sarah: Those suggestions you gave are great. Something that I think is important is you want to make sure that teaching problem-solving is relevant. You mentioned that, but we want to make sure that it's meeting the needs of the family, like what you're suggesting. Think about, when I think about it from a coach's perspective, this might be an opportunity to support the home visitor to come up with some ideas.

For example, if a home visitor asks the family what kind of social problems are popping up at home, or in their socialization settings with their child, it could be, “Oh, my child is taking toys, and they don't think sharing is important.” What you might do is offer different suggestions, but it might be tricky for a home visitor if they don't value sharing. What else could I offer? That could be where coming to your coach and trying to brainstorm and problem-solve or with your colleagues or your supervisor.

If coaching isn't offered, to come up with some different ideas of what they might offer to that family, what they might suggest they teach their child instead. That could be asking for a turn or asking their sibling to give them a turn when they're finished, so there isn't just one right way to do things, and I think sometimes we forget that even as home visitors, our culture and what we value, we bring that into the environment and what we value isn't the only way. That's where getting the input and what the family values because ultimately, you're there to support them to support their child. Remembering that although your culture is relevant as well when you're there to support the family, you want to think about their values and really incorporate it that way.

Some of the responses that are coming in are pretty much in line with what we just talked about. It's looking very similar, getting input from the family, not making assumptions. I'm seeing finding out what they value, learning about their culture is something new that we didn't mention. Getting the parents' input can be really, really helpful. Thank you for those responses.

Joyce: Thank you, and Sarah, like you said, those responses just keep coming in and we encourage you just to keep sharing and keep thinking about, what we need to do to support families in a way that's culturally responsive.

Now, we want to move into our next portion of our time together, and we want to turn our focus just a bit on looking at how home visitors can support families. We've been talking about this, and that's a great segue into this, so just want to explore that just a little bit more. We want to do that by highlighting the resource, and then you have the link to the resource in your viewer's guide for today.

One resource that was developed by the National Center on Quality Teaching and Learning is “Problem-solving in the Moment.” This is a 15-minute in-service suite developed for preschool classroom teachers to help children problem-solve as they arise or in the moment. We've included a link to those materials in the participant's guide.

The content here really talks about these five steps that support and guide children's behavior to encourage problem-solving in the moment. You'll see that the five steps are here: anticipate, be close, provide support, multiple solutions, and then celebrating the success. We're going to explore each of these steps and relate them to how home visitors can partner with parents to guide their child's behavior at home to problem-solve in the moment. Rosalia is going to help us dig into that a little bit more.

Roselia: Anticipate is the first and very important step of this process. As home visitors, we can really work with parents to try and stay one step ahead of problems by recognizing and being proactive. Home visitors can support parents in sensing some of those changes in a child's behavior, as well as their emotions, and then really starting to pay attention to some of those identifying triggers. Home visitors can also help parents be aware as well as to be ready to activate some of those problem-solving steps that we have been talking about.

Let's move on here and talk about the next step, which is to be close. We know that often parents can be very busy, and they're not always going to be physically close when a problem situation presents itself. What parents can do is to relocate themselves and be near the location when the problem is beginning to occur. That's where it becomes important to start to identify some of those triggers, some of the changes in behaviors that are starting to happen, and then start to relocate.

We want to work with parents to recognize some signs that a problem is about to occur so that they can then move themselves closer to that situation at this stage, rather than when the problem is in full swing. We want parents to know that when they are close, it's an opportunity for them to be able to explore and to begin to provide some support for their child. As a home visitor, you can really support families in beginning to pay attention, starting to recognize, and when to offer some of that proactive or preemptive support and figuring out some of those patterns of the behavior.

Being close, time also provides for families an opportunity to model how to remain calm and then some of those gentle approaches to problem-solving so when the parents are close, they're better able to support and then talk through identifying the problem as well as some of those possible solutions that we've been talking about. They can also support their child in regulating their emotions before they get to that heightened level, and then it's going to be a lot harder for them to be able to calm down. Parents being close also provides that opportunity for them to be able to provide that comfort that might be needed before things just really become too escalated and get out of control. Joyce, tell us a little bit about what this support might look like.

Joyce: One of the things that home visitors can explore with their family when it comes to being close and providing support for their child is knowing what level of support to provide to really ensure there is a teachable moment taking place. Sometimes, that support means helping their child stay near and in proximity to where the problem happens so they can problem-solve effectively. Sometimes, that could mean prompting their child to walk through the problem-solving steps.

It can also mean verbal prompting, like, “Do you remember what to do when baby sister doesn't want to take a turn?” or maybe the parent can involve an older sibling in it if they're available, saying, “Hey, let's ask brother what would you do?” Sometimes it's really when children don't have those verbal skills, support can mean to use like visual cues as well and to prompt, that prompts them perhaps, takes them into those problem-solving steps. It really depends; that level of support depends kind of on the specific needs of their child. Knowing it's okay to kind of try out different levels of support to figure out what's needed.

Now we want to talk about the next step, which is multiple solutions. Like we said, there's a whole bunch of different ways to be right about things, and so there can be situations in which one solution maybe a good solution but we know that it may not always work. As children become older, parents can support problem-solving skills by encouraging their child to generate multiple solutions. Maybe with younger children they're going to need parents to support to generate choices or solutions.

This is going to allow children to begin to grow their own toolbox of solutions to draw from when they encounter problems. The solutions don't need to be complicated and can be as simple as maybe using a timer, waiting patiently, or maybe even flipping a coin. Home visitors can support parents by talking through and really helping parents to determine some solutions they can present and help their child when problem-solving, and when problems arise. Sarah, we just want to tag you in here and ask you, do you have any resources in your toolbox that may support families with identifying solutions at home?

Sarah: There's a great resource from the National Center on Pyramid Model Innovations, and it's called the “Solution Kit.” They have a home edition, and it includes some common solutions to everyday social problems and it comes in multiple languages, which is great. Visual supports can be super helpful for young children and this resource might be something that a home visitor can share with families.

Another great resource for teaching problem-solving is this scripted story, we can be problem solvers at home. This scripted story can be used by the family to help children understand the steps for problem-solving and it includes some scenario cards that you can use with children to help them think about solutions to common social problems that they're going to face, either in the home or the community. Those are two of my favorite resources.

Roselia: I love those, Sarah. Those are actually some of my favorites as well and I really love that they're visual and that they really have been designed to help support in the home environment, because often we see that there is resources for center-based children, but I love that these are specifically designed for the home. We have included the information in your Participant's Guide Resource List, so we want to make sure that you take the time to explore those and think about ways that you can utilize those with families that you might be supporting.

Continuing on and thinking about the five steps that we've been talking about, the last step that we want to talk about is just as important as anticipating a problem and that is celebrating success. Reinforcing a child's success in problem-solving really supports their development as effective problem solvers, and as home visitors, we want to be sure that you share this with parents. They can reinforce that celebrating success. It can be formal, or it can be informal. Some examples of that informal celebration might be things such as a high five, acknowledging that they did a really great job, you can give them a thumbs up, a wink, a verbal praise, or even just a hug.

Just letting them know that you're really proud of how they worked through that particular problem. As home visitors, you can really brainstorm some different options and some of those informal gestures that are culturally appropriate and relevant for their family. Then you can also support them in coming up with some more formal ways to celebrate the success. The important thing here is that we want to make sure that parents are acknowledging when children are working through those problems and that they're becoming much more independent so that children feel accomplished and of course if you recognize it in that positive way, they're going to want to do it again. They're going to feel that appreciation.

We're going to watch a video clip. In this video clip, you're going to notice that the setting is a preschool classroom and that there are two children that have encountered a problem. We want you to take note on how the teacher handles the situation to really engage the children in working through problem-solving. In your participant's guide, you have some space, and we want for you to take some notes and really pay attention to some of the strategies that the teacher is using. It is a classroom; however, think about how this scenario might play out, perhaps in a home between two siblings or even at a group socialization between two children. Let's take a look.

[Video begins]

Teacher 1: Janny, what's the problem? You're getting it to make the fort and it looks like Amy's holding it too. Thanks, Elena for moving so I could get up. So what are we going to do about it? You both want the same block? What are we going to do about it? How are we going to fix the problem? I'm going to hold the block for a minute while you guys help figure it out. What's your idea?

Child 1: [Inaudible]

Teacher 1: You want to play with it over there. Shall we find out what Jammy's idea was? What was your idea, Janny?

Child 2: [Inaudible]

Teacher 1: Oh, and she thinks she needs it for that building. So, you both need this block for two different buildings. Do you want to look for an idea in the basket? Grab the book. See what you can come up with. There's another one over there, right. I think Amy's got the book. What are we going to do? She's looking, so let's play together, so that would be building the same building together.

Take a break, so you just take a break from building. Wait until she's done. One more minute, so she would have it for a minute and then you would have it for a minute. You build with something else, maybe next time. Playing together. You would build it together. Do you want to build together, Janny? Look at Amy's talking to you. Sorry, I just said it and Amy was saying it. Sorry about that, Amy. Here. So Amy, you're going to help Janny build her tower.

Child 1: Let's do this one.

Teacher 1: Excellent. You guys are expert problem solvers.

[Video ends]

Joyce: We see some of the strategies coming through in the Q and A, we'll ask you to keep putting those out there for us, and just want to check in with Rosalia and Sarah to say what did you guys notice anything there about some of those great problem-solving skills that we saw happening?

Sarah: My favorite part of that video is that she really supported those two children to solve their own problem. She gave them support by prompting them to find the materials to help them problem solve. She read through some of the problems with them, or solutions with them, but ultimately the teacher didn't solve the problem for them. And that was really great to see because I think sometimes as adults, we want to be the fixer and in this video the children were really the experts. They were the expert problem solvers here. I thought that was…

Roselia: I agree, Sarah. I really love that and just the anticipation from the teacher, but also having their little solution book that they can kind of, the visual to work through and see they had multiple choices to choose from. That was my favorite part.

Joyce: Yeah, definitely lots to see in that one. I like that one. I think watching the adult and also watching the kids and how they react to that. Sarah, we just want to give you some space as we're kind of wrapping up to hear a little bit more from your coaching experience and just maybe some more tips for supporting home visitors and partnering with families.

Sarah: Sure. It's really important to remember that parents are their children's' best teachers and most children already, most of what children know or what they know when you come into a relationship with that family, has been learned by their parents. As home visitors, when we partner with parents, we really want to set the stage to provide those intentional opportunities for learning within the home setting.

These tips for child size problems that children can solve with the help of their parents or on their own. Here are some tips that you can share with families to set the stage for their child to become problem solvers. One would be to help the child to relax. When children are faced with a problem, they can become upset, frustrated, angry, they might get their feelings hurt or even cry.

This is not the time to try to solve the problem. When the child becomes calm, we want to help them to work through their problem, but when they're at the height of these emotions, that's not the time. We want to regulate, use some calming strategies to get them to calm down. Then we can support them to problem solve. You can support families to understand that supporting children to calm down is a really important step of this process.

We want to make sure that we're giving uninterrupted time. As home visitors you want to partner with parents to help them understand that developing problem-solving skills is complicated and it takes time. Giving them uninterrupted time that's not rushed to talk through and support them to thinking through problems. Also, we want parents to feel like they are a coach. When we're talking about being a coach, we're not talking about home visitors coaching parents but what we mean here is that children at a very young age are still developing these skills.

We want you to work with parents on developing their ability to identify opportunities and support their children through asking questions and helping their children think and share through what maybe these problems and solutions might be. Active listening is a really important part of this process, as parents it can be hard sometimes, we want to throw out our ideas and suggestions but active listening for children is so important.

Here are some strategies that a home visitor can share with families, and we want you to jot down some notes in your participant guide. Encourage parents to withhold from solving those problems for children, so support them to support children and not solve them for them. Support parents in developing questions that they might ask when problems arise. Help parents to identify when they are, their critical solutions to their child is proposing, so try not to judge the solution. Sometimes they may be silly; let them try it out. Provide that active listening. All those strategies, you can remember those that will support families.

Joyce: Definitely, and we've included all of these tips in a handout, and that's part of your participant's guide as well. You may think, "What's my role in supporting some of these practices?" Rosalia, if you want to give maybe one kind of tip to close us out, what do you think that one thing would be regarding the role of the home visitor?

Roselia: I think the important thing, and I think Sarah has kind of really touched on this throughout, is just really taking the time to listen to the family. Finding out what's important to them, and then just kind of being a facilitator if you will — just kind of really asking some of those haunting questions to get the parent to start thinking about some of those steps that we talked about, like anticipating that behavior, looking at problem-solving as an opportunity for learning, and just helping children to really put words to those emotions that sometimes even we as adults struggle with.

I think really being that partner, that reflective partner with the parent, and then providing some of these strategies to help them work through that and again just really seeing it as an opportunity and not necessarily as a behavior that challenges us. Just kind of taking that time to explore with their child and just giving them the words for those emotions to kind of help them become more aware as they kind of go out into the world and face some of those social conflicts if you will. That would be my suggestion.

Joyce: I think that's a great one to leave us with today. Thank you, Sarah, so much for joining us. Thank you everyone here. If you have any questions or anything, drop them in the Q and A. Also, feel free to reach out to us, we have to keep this conversation going, and we will see you guys next time. Thank you.

How young children approach and solve problems is critical to their overall development. Problem-solving supports how young children understand the world around them. It can impact their ability to form relationships as well as the quality of those relationships. Supporting the development of problem-solving skills is not a one-size-fits-all approach. Explore strategies and resources home visitors can use to partner with parents to strengthen and nurture these skills and help children cope with challenges as they arise.

Note: The evaluation, certificate, and engagement tools mentioned in the video were for the participants of the live webinar and are no longer available. For information about webinars that will be broadcast live soon, visit the Upcoming Events section.

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Age Group: Infants and Toddlers

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Series: Home Visiting Series

Last Updated: April 5, 2024

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6 Strategies for Promoting Student Autonomy

These techniques foster independence and show students how to help themselves—and their peers—understand and complete tasks.

Four girls look at a laptop together in class.

Flexible classrooms rely on students exercising a certain degree of independence. If teachers want to maximize their time working with individuals and small groups, for example, they need the rest of the class to be self-sufficient.

Unfortunately, as teachers know too well, children of all ages often default to dependence on adult help. Instead of ridding the classroom of tasks that require autonomy, teachers can equip students with the skills and know-how to be their own best assistants.

Six Simple Strategies for Promoting Student Autonomy

1-2-3 Then Me: This approach asks students to rely first on their own and their peers’ understanding of a task. Give students one minute to go over the directions silently, two minutes to discuss the directions with each other, and three minutes to plan their approach to the task. Only then can they ask for assistance. Or give a one-minute explanation of the directions to the whole class in place of or prior to students reading the directions silently or in pairs.

Recorded Directions and Responses: These are simple but powerful tools, especially for students whose reading and writing skills are still developing. With the voice memo function on a device, record yourself giving directions. (You can use an accent or character voice, for fun.) Students play back the directions when needed, rewinding to listen to trouble spots or simply to hear your explanation again. Place the device at the station or center where students complete their tasks, or post the file on a class website or app like Seesaw. Alternatively, students can record themselves or a peer reading or explaining directions aloud for later playback.

Digital recordings build independence in task completion if students can also record their response to a task or their skill performance. This frees the student from having to wait for an audience and allows the teacher to work with individuals or small groups. With younger children, responses can be played back directly from the devices. Older students can upload their responses to a dedicated site or folder.

Resource Files: Another self-help mechanism when the teacher isn’t available. These files include troubleshooting tips for routines and tools that students use on a regular basis. For instance, what to do when the iPad screen freezes or how to push through writer’s block. Resource files can include extra graphic organizers, peer editing protocols, and rubrics. The files can be physical (i.e., folders with paper materials inside) and placed in a prominent area of the room, or digital files in a clearly marked, easy-to-access spot on a device.

Hint Cards: Similar to resource files, but lesson-specific. The teacher in this video , for example, has anticipated likely trouble spots with the mathematics tasks students are working on. Her hint cards ask probing questions that she would pose to students if they were stuck, and students use the cards before consulting her. Over time, students internalize both the questions and the process for getting unstuck.

Colored Cups: This self-monitoring and signaling strategy builds students’ skills in deciding if and when they need teacher help. Each group (or individual) receives a stack of three colored cups (ideally, green, yellow, and red to mimic traffic lights). The teacher instructs the student to display the cup that matches how they’re working:

Green cup on top: I am/we are fine—no teacher help needed.
Yellow cup on top: I/we need teacher help but can continue working while waiting for it.
Red cup on top: I/we need teacher help immediately and have stopped working.

The teacher monitors the cups while circulating, and works with groups according to urgency. At first, teachers may find that students regard every stumbling block as a red-cup situation. This is another opportunity to encourage independence: Point out when the cup should be yellow and direct the student or group to what they can work on while waiting for you. Leave for a few minutes and return to assist if the top cup is yellow or red.

Question Chips: These help students decide whether their questions about tasks are “must ask the teacher” or “could find out myself.” Each student—or group—receives a limited number of question chips (e.g., pennies, paper squares, or game chips) for the class period or longer. These represent the number of times students can call on the teacher for help. If students have only a few chips, they’re less likely to raise their hands and summon the teacher for easy-to-answer questions.

The spirit of question chips is not to squelch inquiry or discourage students from seeking clarity—the idea to for them to ask themselves, “Is this something that I already know, will find out soon, or can ask a peer—or do I need to ask this now so that I understand?” As with the colored cups, teachers can be instructive as everyone learns how to use the chips. For example, if a student poses a procedural question, say “Do you really want to use a chip on that?” and make a general suggestion about when, where, or how to find the answer.

To be effective, these strategies must be taught and modeled. Introduce them as needed, and use those that suit your subject, students, and style. Students won’t become independent overnight, but in time and with practice, they can all learn how to help themselves.

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Data Descriptor
Open access
Published: 25 April 2024

Students’ performance, attitude, and classroom observation data to assess the effect of problem-based learning approach supplemented by YouTube videos in Ugandan classroom

Nicholus Gumisirizah 1 ,
Joseph Nzabahimana 1 &
Charles M. Muwonge 2

Scientific Data volume 11 , Article number: 428 ( 2024 ) Cite this article

Metrics details

Applied physics

In response to global demands, Uganda’s Vision 2040 seeks to transform the country into a modern and prosperous nation by implementing Sustainable Development Goal (SDG) 4, focusing on equitable and quality education. The 21st-century workforce requires individuals who can effectively navigate complex workplace challenges. This dataset was gathered from Form-2 Ugandan secondary school students (aged 12 to 15) across 12 schools in the Sheema District. The dataset comprises three types of data: students’ performance in a physics topic (simple machines), their attitudes toward problem-solving and critical thinking when learning physics using Problem-Based Learning (PBL) supplemented by YouTube videos, and classroom observations documented with the reformed teaching observational protocol (RTOP). The intervention of teaching using PBL was executed in 2022, collecting data from 973 lower secondary school students. The intervention involved three approaches: one group (144 students) received PBL along with YouTube videos, another group of 482 students received PBL alone, and a third group (347 students) was taught using the traditional method. This data article explains the study’s data creation, collection, and analysis process. The dataset holds significance for secondary school teachers, policymakers, and researchers, offering insights into the impact of PBL with and without ICT resources on learning physics and students’ attitudes toward these learner-centered approaches.

A meta-analysis to gauge the impact of pedagogies employed in mixed-ability high school biology classrooms

Secondary school students’ attitude towards mathematics word problems

Dataset and validation of the approaches to study skills inventory for students

Background & summary.

Physics education in secondary schools plays a vital role in developing students’ social, physical, leadership, and problem-solving skills. Understanding physics concepts equips learners to know how things work, enabling them to apply this understanding to real-life situations 1 . The physics teaching is structured around activity-based 2 chapters and topics, emphasizing hands-on experiences 3 and practical applicability in everyday life. However, many students find physics challenging, necessitating an active teaching approach. Teaching in physics remains dynamic and interactive, with teachers adopting various strategies to engage students actively. Reciprocal teaching involves dialogues between the teacher and small student groups, while peer collaboration fosters cooperative work on class activities. Problem-Based Learning (PBL) 4 , 5 , 6 is a student-centered approach that encourages group-based learning and teacher facilitation. It has been widely adopted in various educational fields, promoting problem-solving in learning environments. Implementing PBL follows a five-stage process:

Finding a problem

The teacher prepares a task for students to investigate, stimulating problem-solving abilities.

Organizing ideas on the problem

Learners investigate the problem, generate ideas, and receive probing questions from the facilitator to stimulate critical thinking.

The teacher facilitates the distribution of learners into groups, each focusing on solving a particular problem related to the main task. Responsibilities are assigned within each group, promoting cooperation.

Present findings

Learners present solutions to the problem and receive feedback from peers, consolidating their learning outcomes.

Generalizing

Problem-solving leads to the development of skills essential for solving complex, real-world situations. These skills, including problem-solving, creativity, communication, cooperation, and innovation, prepare students to adapt to change and overcome 21st-century challenges.

Integrating YouTube videos as Information and Communication Technology (ICT) tools within a PBL approach offers a multifaceted strategy to enhance physics education 7 , 8 . High-quality videos aligned with curriculum objectives introduce real-world problems and cater to diverse learning styles. Interactive features and accessibility allow continuous learning, and educators can curate playlists to align with curriculum goals. The flipped classroom model 9 combines videos with problem-solving discussions 10 , creating a dynamic learning environment that deepens students’ understanding of physics concepts and their practical applications.

Physics is a subject that holds a significant position in promoting scientific literacy, critical thinking, and essential life skills. However, conventional teaching methods often struggle to engage and empower students in the subject matter effectively. This inadequacy is a pressing concern, as it can hinder students from developing a strong foundation in physics, which is essential for their academic and practical pursuits. This study was critically important due to the existing challenges within physics education in Ugandan secondary schools. Incorporating innovative teaching approaches, such as PBL supplemented by YouTube videos, becomes pivotal in addressing these challenges. These methods can enhance students’ comprehension of physics and nurture vital skills like problem-solving, creativity, communication, cooperation, and innovation. These skills are indispensable for students to thrive in a rapidly evolving, knowledge-driven world.

Sharing the data generated through this study is equally significant. It is a valuable resource for educators, policymakers, curriculum designers, and researchers. By making this data accessible, the study contributes to the ongoing efforts to improve the quality and relevance of secondary education in Uganda. Educators can utilize this data to adopt innovative and effective teaching methods that align with the goals of the educational system, ultimately enhancing students’ performance and fostering lifelong learning. Policymakers and curriculum designers can use the insights derived from this data to conduct essential reviews and make informed decisions about teacher competence and the adoption of innovative teaching methodologies. Furthermore, researchers in similar fields can leverage this data to understand better the impact of PBL and the use of multimedia resources in education. This data identifies gaps and challenges and offers potential solutions and avenues for further research.

This data-sharing article presents insights into the effects of Problem-Based Learning (PBL) supplemented by YouTube videos on students’ comprehension of simple machines in physics within Ugandan lower secondary schools. The research collected data from 973 students, encompassing both public and private schools in the Sheema district of Uganda. Three primary types of data were collected: students’ performance data, attitude data, and classroom observation data.

Performance data was acquired through a Physics Learning Achievement Test (PLAT), involving students from various school types and teaching methods. Attitude data were collected via two surveys, one focusing on problem-solving ability (AAPS) and the other on critical thinking ability (CTMS) under PBL with YouTube videos. The Approaches to Problem-Solving Survey (AAPS) and the Critical Thinking Motivational Scale (CTMS) are measurement tools commonly used in the field of physics. The AAPS assesses various strategies individuals employ when solving problems, while the CTMS evaluates motivational factors influencing critical thinking abilities. The Reformed Teaching Observation Protocol (RTOP) assessed classroom practices and teaching methods.

The dataset, available in raw, filtered, and analyzed formats, offers valuable insights into the impact of innovative teaching methods on student performance, attitudes, and classroom practices. It addresses critical questions about the effectiveness of PBL approaches, with potential implications for science education in Uganda.

This dataset intends to assess the impact of PBL when supplemented with YouTube videos on Ugandan form-2 lower secondary schools in learning simple machines. The following are the research questions:

To what extent do PBL and PBL supplemented with YouTube videos enhance students’ conceptual understanding of simple machines in physics?

What are the problem-solving and critical thinking levels brought by learning with PBL supplemented by YouTube videos?

How is physics teaching reformed when learning simple machines in physics with PBL supplemented by YouTube videos?

Are there differences in students’ academic achievement for school type (government alongside private school)?

Ethics statements

The research project rigorously adhered to ethical standards established by the University of Rwanda College of Education’s (UR-CE) Research and Innovation Unit under the ethical protocol number Ref. 03/DRI-CE/078/EN/gi/2021, dated 30th November 2021. All necessary permissions were obtained systematically and ethically, as outlined in the research project description. Here is a summary of the ethical considerations and recruitment process:

Ethical protocol

The research project adhered to the ethical standards and principles of the UR-CE)‘s Research and Innovation Unit. The protocol number and approval date are explicitly mentioned, demonstrating a formal ethical review.

Permissions from authorities

The Ministry of Education and Sports obtained formal permission to access schools through the Permanent Secretary’s (PS) office. The PS communicated with the Chief Administrative Officer (CAO), District Education Officer (DEO), and Resident District Commissioner (RDC) to secure the necessary support for the study.

Engagement with schools

With the approval from the CAO, the DEO contacted school heads to inform them about the research study. The school heads responded positively and even provided physics teachers with three-day problem-based learning (PBL) training as part of the research. It is worth noting that all participating teachers held teaching qualifications, and as part of the research process, we provided them with a three-day training session specifically focused on implementing PBL interventions. This training aimed to ensure consistent delivery of PBL across treatment classrooms and schools, thereby mitigating variations attributable to individual teaching styles.

Informed consent

Teachers and students, with parental consent, willingly participated in the research study. Informed consent forms were signed, indicating they fully understood the study’s purpose, procedures, potential risks, and benefits. Anonymity was ensured for students by not including their names on the test papers.

The research employed purposive sampling to select 973 students from 12 schools. These schools were divided into three groups, each with a different teaching method: PBL with YouTube videos, PBL alone, and Traditional teaching.

Geographic considerations

Schools were selected from different town councils at extreme ends of the district, sharing similar characteristics suitable for the study. This approach helps ensure that the study’s findings are robust and generalizable.

Research design

The study utilized a non-equivalent comparison group pre/post-test design (Creswell, 2012). The study involves Form 2 students from six Sheema District, Western Uganda schools. Three selected schools were public, while the remaining three were private, offering a diverse representation of school types in the district. The selection of schools was purposeful, aiming to ensure diverse representation and maximize the study’s validity. This approach allowed for the strategic allocation of schools to treatment or control groups based on specific criteria pertinent to the research objectives. Notably, the selection criteria considered factors such as geographical location, school size, academic performance, and availability of resources to ensure a balanced representation of different educational contexts. The traditional method, characterized by conventional lectures supplemented with textbooks and teacher-centered content delivery, was employed in control group schools. Students in this group primarily learned through note-taking with minimal demonstrations. Conversely, four other secondary schools were designated as the first treatment group, where Problem-Based Learning (PBL) was implemented. Four additional schools comprised the second treatment group, which utilized PBL supplemented by educational YouTube videos. These groups collectively engaged in constructing knowledge and enhancing conceptual understanding. The participants in the study were form-2 students, ranging in age from 12 to 15 years, who were already enrolled in the schools.

We provide a performance (achievement) test to all 973 students before and after teaching interventions in all groups. We administered an attitude survey (motivation scale) and observed classes in the group that used PBL and YouTube videos. Table 1 presents the sample size under the teaching intervention of design groups implemented.

The objective of the performance test was to gauge students’ grasp of conceptual understanding acquired through the implementation of a problem-based learning approach following the completion of the topic on simple machines. The test, spanning 25 minutes, consisted of ten questions sourced from practice exercises on simple machines within form-two secondary learners’ physics textbooks. The National Curriculum Development Center and the Ministry of Education and Sports in Uganda approved these textbooks. The examination encompassed themes outlined in the approved lower secondary curriculum physics syllabus, covering concepts like the applications of simple machines, mechanical advantage, velocity ratio, and efficiency of machines. Specific topics included levers (covering classes and applications), pulley systems (encompassing types, applications, mechanical advantage, velocity ratio, and efficiency), inclined planes (including applications, mechanical advantage, velocity ratio, and efficiency), wheel and axle (exploring understanding, applications, and velocity ratio), gears (addressing simplification of work, applications, and velocity ratio), and methods of enhancing machine efficiency. The test was validated by four researchers from Mbarara University of Science and Technology (MUST) and the University of Rwanda College of Education (URCE). Test 1 was scored in MS Excel with “IF EXCACT” function, while Test 2 was manually marked, and results were entered in the same software.

Attitude surveys were all adopted from existing literature. Critical Thinking Motivational Scale (CTMS) was used as our Survey 1 and was adapted from Valenzuela et al . 11 , while Attitudes and Approaches to Problem-Solving Survey (AAPS) was used as our Survey 2 and was adapted from Singh and Mason 12 and available at Physport ( https://www.physport.org/assessments/assessment.cfm?A=AAPS ). Problem-solving and critical thinking are integral to effective physics education. They deepen students’ understanding by connecting theoretical concepts to real-world situations 13 , 14 . These skills encourage active engagement and foster analytical abilities, allowing students to break down complex problems. Additionally, they promote creativity, help apply theory to practice, and cultivate logical reasoning. Problem-solving and critical thinking prepare students for future challenges in scientific and engineering fields, encourage collaboration, boost confidence, and instill a mindset for lifelong learning. Incorporating these skills into physics teaching enhances academic performance and equips students with valuable personal and professional growth tools. We adopted all 19 items from CTMS and only 31 items from AAPS to meet our research aim. Thus, the last two items (32 and 33) in AAPS were removed as they were not related to the content delivered in our study. All these surveys were rated on a Likert scale (from strongly disagree to strongly agree). Items 1–4 are related to expectancy, items 5-8 to attainment, items 9-12 to utility, items 13-16 to interest, and items 17-19 to cost.

Classroom observation data was collected with the famous standardized reformed teaching observation protocol (RTOP) from Pibun and Sawada 15 and is available at Pysport ( https://www.physport.org/assessments/assessment.cfm?A=RTOP ). RTOP proved its validity and reliable results across the globe 16 , 17 , 18 , 19 with its potential to reveal reformed teaching while implementing a new teaching method. It comprises 25 statements where each item is evaluated on a 5-scale. It is scored 0 when such practice was not found in a lesson and 4 when a certain practice was very well described or observed in a delivered lesson. During classroom observation, an observer sits in the classroom and observes what the teacher and student do. He/she may take notes on what is happening but wait until the class is over to rate these 25 items.

Data Records

All data described in this descriptor are deposited in figshare ( https://figshare.com/articles/dataset/RTOP_Data_for_the_implementation_of_Problem-based_learning_in_a_Physics_classroom_Uganda/23974902 ) 20

To evaluate the impact of PBL teaching intervention on students’ performance and attitude toward learning physics, we gathered three data types (performance, attitude, and observation) presented in five datasets (two performance tests, two attitude surveys, and one classroom observation).

Students’ performance data

The student performance data comprises two datasets or MS Excel files. The first file contains data for test one titled “Performance data _ Test 1 (Multiple choice) _ 12102022 figshare.” This file contains data from ten multiple-choice questions. The file contains three sheets. The first sheet shows test items (all ten questions), the second presents pretest answer choices, and the third presents post-test answer choices or results. Each results sheet shows the school code (column B), student code (column C), school type (column D), and treatment group (column E) as variables. From column “F” to column “O” we see student answer choices under each test question. From column “Q” to column “Z” we marked the test (one score for each correct question). Column “AB” shows the percent score. Row “3” shows the expected correct answer, while row “4” shows variables and the number of test items.

The second file contains data for test two titled “Performance data _ Test 2 (Problem solving) _ 12102022 figshare.” This file contains data from ten-word problem kinds of questions. The file contains three sheets. The first sheet shows test items (all ten questions), the second presents pretest scores, and the third presents post-test scores or results. Each results sheet shows the school code (column C), student code (column D), school type (column E), and treatment group (column F) as variables. From column “G” to column “P” we see student scores under each test question. Column “R” shows the total score, while column “S” shows percent score. Row “3” shows the assigned score when each question’s expected correct answer was provided. Row “4” shows variables and several test items.

Students’ attitude data

The student attitude data comprises two datasets or MS Excel files. The first file contains data for the first survey titled “Motivation data _ Survey 1 (Critical thinking ability) _ 12102022 figshare.” This file contains data from 19 items of critical thinking ability survey. The file contains two sheets. The first sheet shows the pre-test results, while the second shows the post-test results. Each sheet shows the school code (column C), student code (column D), school type (column E), and treatment group (column F) as variables. From column “F” to column “O” we see student answer choices under each test question. From column “G” to column “Y” we see student answers or agreement (1: STRONGLY DISAGREE, 2: DISAGREE, 3,: NEUTRAL, 4: AGREE, AND 5: STRONGLY AGREE) to each item of the survey. Row “2” shows the survey title, while row “4” shows the variables and number of survey items.

The second file contains data for the second survey titled “Attitude data _ Survey 2 (Problem solving ability) _ 12102022 figshare.” This file contains data from 31 items related to problem-solving ability in learning physics. The file contains two sheets. The first sheet shows the pre-test results, while the second shows post-test results. Each sheet shows the school code (column C), student code (column D), school type (column E), and treatment group (column F) as variables. From column “G” to column “AK” we see student answers or agreement (1: STRONGLY DISAGREE, 2: DISAGREE, 3,: NEUTRAL, 4: AGREE, AND 5: STRONGLY AGREE) to each item of the survey. Row “2” shows the survey title, while row “4” shows the variables and number of survey items.

Classroom observation data

The file for classroom observation data is titled “Classroom observation data _ RTOP for video & pbl group _ 12102022 figshare” and contains only one sheet. From column “B” to column “C” we see RTOP while the following columns (D-AA) present data. Row “10” shows school codes, while row “5” shows several observations and frequencies under each school supplied with PBL and YouTube videos teaching intervention. The data range from 0 (never occurred) to 4 (very descriptive).

Technical Validation

Initially, we had 20 problem-solving questions, but evaluators rated 10 as valid, which were included in the final administration. We also initially had 15 multiple-choice questions, and evaluators rated 10 as appropriate and aligned with the study objectives. A pilot study was conducted with 90 students to evaluate the face validity and reliability of the questions. We assessed the reliability of these items using a split-half method and obtained a high reliability (r = 0.87) for multiple-choice items and a medium reliability (r = 0.68) measured by the Pearson product-moment correlation coefficient for problem-solving items. The split-half reliability assumes that the two halves of the test are equivalent in difficulty and content 21 .

CTMS and AAPS

During our pilot phase, the internal consistency of CTMS, assessed using Cronbach’s alpha, was found to be high (0.793) for all 19 items, medium (0.428) for expectancy, (0.411) for attainment, (0.686) for utility, (0.574) for interest, and (0.594) for cost. The AAPS exhibited an internal consistency reliability of Cronbach’s alpha = 0.685. It is important to note that the AAPS contains nine items formulated negatively. Therefore, for a positive attitude, students were required to respond with ‘Disagree’ or ‘Strongly disagree’ to these items (1, 3, 5, 8, 11, 12, 16, 23, and 30). Consequently, the reliability of the 22 positively formulated items was 0.601, while that of the negatively formulated items was 0.480.

Before observing actual classes, we underwent a 2-hour training session and watched and coded a YouTube classroom video on physics. The inter-rater agreement between the first author and the assistant exceeded 80% on two occasions, indicating the reliability of the data.

Scope and potential limitations

In our study, we recognized the significance of investigating potential bias in the results obtained from students in both private and public schools. To ensure the credibility and robustness of our findings, we conducted a comparative analysis to determine whether any notable disparities existed between these two groups. Our data collection process was comprehensive, encompassing a diverse range of schools, including both private and public institutions. This approach allowed us to capture a broad spectrum of socioeconomic backgrounds and educational settings. The study itself involved Form-2 students who were enrolled in schools situated in different town councils at opposite ends of the district. Despite their geographical diversity, these schools shared pertinent characteristics relevant to our research objectives. To facilitate our investigation, we categorized these schools into distinct treatment groups, comprising PBL alone and PBL with videos, along with a control group following traditional teaching methods. Importantly, we deliberately chose to maintain the existing class arrangements in these schools. Our commitment to preserving each school’s established class organization and cultural norms guided this decision.

However, it is essential to acknowledge the limitations inherent in the research design. One notable limitation is the observation of attitudes, which was limited to the student group exposed to the PBL with the video teaching method. This restriction may impact the generalizability of the findings, as attitudes toward learning may vary among students exposed to different instructional methods. Future research endeavors could consider incorporating measures to assess attitudes across all treatment groups to provide a more comprehensive understanding of the intervention’s effects.

The current data files do not contain information on individual teachers due to the scope and focus of the study. These variables could include educators’ teaching experience, pedagogical approach, content knowledge, and instructional effectiveness. Since we recognize the significance of teacher impact, we would consider incorporating such variables in future research projects to provide a more comprehensive analysis of instructional effectiveness and its associated factors.

Regarding the decision to maintain existing class arrangements in schools, particularly considering cultural norms, it is crucial to recognize its potential influence on the study outcomes. The intervention’s impact may have been influenced by preserving the existing class structures, including student composition and dynamics. For instance, certain class arrangements may foster greater collaboration and engagement, while others may present challenges in implementing collaborative learning approaches such as PBL. Therefore, future studies could explore the relationship between class arrangements and instructional effectiveness to provide insights into optimizing learning environments.

Usage Notes

Value of the data.

The data presented is valuable and beneficial to science education in Uganda as it elucidates the status of students’ content knowledge and their perceptions about learning simple machines with PBL approaches.

Policymakers and curriculum designers have the opportunity to conduct essential reviews that highlight the competence of teachers. This process can pave the way for advocating innovative and relevant teaching methodologies, subsequently informing the identification of professional development requirements for educators.

Researchers in similar fields can re-use these data to measure the effect of PBL intervention on student achievement, identify gaps, and predict possible remedies. Thus, data can be analyzed using various variables such as teaching intervention and school type.

Code availability

No custom code was used.

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Acknowledgements

We acknowledge the African Center for Excellence for Innovative Teaching and Learning Mathematics and Science (ACEITLMS) for funding this study and the authors of the research tools we used to free them to use. All study participants, teachers, and school headteachers are also well acknowledged.

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Gumisirizah, N., Nzabahimana, J. & Muwonge, C.M. Students’ performance, attitude, and classroom observation data to assess the effect of problem-based learning approach supplemented by YouTube videos in Ugandan classroom. Sci Data 11 , 428 (2024). https://doi.org/10.1038/s41597-024-03206-2

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Graduating Business Fellows stand together on a staircase.

The 2024 Toast recognizes achievements of Lindner’s Business Fellows

Students saluted for accomplishments inside and outside of the classroom.

The Carl H. Lindner College of Business Office of Inclusive Excellence hosted its annual Toast event for the Business Fellows program April 18 at The Graduate Hotel Cincinnati.

Students, Lindner staff and faculty, alumni, corporate partners and community leaders attended the celebration of the Business Fellows graduates. Business Fellows supplies underrepresented students with wraparound support to attain professional and personal success, while facilitating a culture of inclusion and belonging at Lindner and UC.

Nick Castro , assistant dean, Office of Inclusive Excellence, expressed gratitude to attendees for being pieces of Business Fellows’ “big puzzle” in his opening remarks.

From left: Eugene Burse, BBA ’26; Kyle Caisaguano, BS ’24; Ejiro Agoba, BS ’24; Hailey Manuel, BBA ’26, Quincy Allfree, BBA ’24; Briana Jarrell, BBA ’24; and Julian Hill, BBA ’23.

“When you put that puzzle together, what we have is our Business Fellows being supported and successful. Whether you are part of an advisory group, the Dean's Cabinet, a donor or a scholarship supporter, a faculty or staff member, or a family member, everybody in this room has impacted each other in some way, shape or form. And I think those are positive ways, shapes and forms.”

Castro then introduced WCPO reporter Raven Richard, who emceed the Toast for the third successive year. After acknowledging past and current Business Fellows Executive Board members, Richard thanked the event’s leadership sponsors: PNC Bank, Truepoint Wealth Counsel and Western & Southern Financial Group. Also recognized were companies who have sponsored the Office of Inclusive Excellence throughout the current academic year.

Sycamore Capital
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Cardinal Health
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Dean Lewis spotlights career trajectories, problem solving

Lindner Dean Marianne Lewis, PhD, stands with representatives from Cintas, sponsors of Lindner’s Office of Inclusive Excellence.

Lindner Dean Marianne Lewis , PhD, delivered the keynote address, touching on Business Fellows' origins and its growth before coaching the students on career progression.

“It’s going to start slow, and you’re going to build your network. You’re going to start developing your skills. You’re really going to know your job, and it’ll get easier, faster — and it will be amazing what you can do. A big part of that climb is innovation. It’s about problem solving with creativity, collaboration and some push.”

Lewis also spoke about interacting with Business Fellows alumni, rising expectations and ambitions, and more.

“They talked about the challenges and opportunities of the rungs in your ladders. Some of us don’t have all the rungs, and it’s awfully hard to get from rung to rung when you’re missing six in between. And they made the point that Business Fellows was vital for their rungs. The corporate partners and alumni were vital for their rungs. (Last week) they were saying, ‘We want to be rungs.’ And I share it with you because I hope we can all remember that we can be someone’s rung.”

“If we are going to truly model a culture of inclusive excellence, we need to be reaching out to others who don't have all the rungs. Because, from what we've learned, we know we have a special sauce to help make it happen. We know how to do the wraparound support.”

“Our expectations are rising. Our ambitions are rising. And, together, we will keep rising. I’m grateful to have a community that we can continue to push the envelope with in so many special ways.”

Student honors

Richard returned to the stage to announce the evening’s awards, beginning with the PACE Honors. The PACE Honors recognize students who best exemplify Professionalism, Academics, Character and Engagement (PACE) , principles essential to student development at Lindner. The following students were acknowledged in this category:

Professionalism: Eugene Burse, BBA ’26
Academics: Kyla Ward, BBA ’27
Character: Matt Santiago, BBA ’25
Engagement: Nariah Edwards, BBA ’26

Business Fellows was, is and will always be one of the main reasons why I know I belong. Once you feel and begin to treasure this relatedness through belonging, the mindset becomes being the best person you can be, so that you may inspire your loved ones.

Joshua Moore, BBA ’23

Next, outstanding first-, second-, third- and fourth-year students were honored for their passion for the Business Fellows community and its resources. The following students were recognized in this category:

First Year: Mirsayah Wasnuk, BBA ’27
Second Year: Hailey Manuel, BBA ’26
Third Year: Gabe Galiatsatos, BBA ’25
Fourth Year: Quincy Allfree, BBA ’24

The Fellows Impacting Fellows honor was bestowed upon Prince Kalala, BBA ’24, for going above and beyond in impacting his peers with mentoring and relationship development.

Celebrating seniors, the Toast

After an invocation of gratitude from Quincy Allfree, BBA ’24, and dinner and lighthearted conversation, Richard returned to the stage to individually honor graduating Business Fellows, who received a commemorative plate and a stole to wear at graduation.

Paola Alcantara
Quincy Allfree
Zachary Bahri
Savana Berhane
Kyle Caisaguano
Samoya Cochrane
Lance Entsuah
Saron Eyouel
Holly Giese
Julian Hill
Tierra Hudson
Brianna Jarrell
Prince Kalala
Kendall Kelly
Joshua Moore
Dagim Negash
Elizabeth Piper
Kayla Stone
Alexia Thomas

Joshua Moore, BBA ’23, raised his glass to his fellow Business Fellows after delivering the closing toast.

Joshua Moore, BBA ’23, delivered the closing toast with heartfelt remembrance and thoughtful perspective of his time with Business Fellows.

“Business Fellows was, is and will always be one of the main reasons why I know I belong. Once you feel and begin to treasure this relatedness through belonging, the mindset becomes being the best person you can be, so that you may inspire your loved ones.”

Moore ended with advice for younger students.

“Please don’t view Business Fellows as just another club, because trust me, if you put the time in, it will give you so much more beyond academia and professionalism. It will make you a better person, a better friend, a better teacher, and so much more.”

Featured image at top: 2024 Business Fellows graduating seniors. Photos/Joseph Fuqua II.

Interested in Business Fellows?

The Business Fellows program provides underrepresented students from a range of backgrounds with wraparound support to achieve professional and personal success. Through career connections, community and leadership development, Business Fellows empowers future business leaders to solve problems that matter and advances a culture of inclusion and belonging within Lindner and at the University of Cincinnati.

Lindner Diversity & Inclusion
Lindner College of Business
Business Fellows

Lindner Business Fellows homecoming event puts growth on full display

October 24, 2023

The Carl H. Lindner College of Business’ Office of Inclusive Excellence hosted current students, alumni and supporters from across the university to celebrate the office’s signature Business Fellows program on Oct. 12. The event also recognized the program’s founders and early champions.

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It has been widely adopted in various educational fields, promoting problem-solving in learning environments. Implementing PBL follows a five-stage process: Finding a problem
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Eight Instructional Strategies for Promoting Critical Thinking

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‘Before-Explore-Explain’

An Issue of Equity

Critical Thinking & Student Engagement

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Encourage Independence

Be sensitive

Encourage Thoroughness and Patience

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1. Brainstorm bonanza

2. Problem-solving as a group

3. Clue me in

4. Survivor scenarios

5. Moral dilemma

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Thinking Classrooms: How To Promote Critical Thinking In Class

What are the 14 Practices of a Thinking Classroom?

1. Classroom Culture of Thinking

2. Opportunities to Think in Groups

3. Vertical and Non-permanant Workspaces

4. Room Layout

5. Answer Questions that Promote Thinking

6. Give Tasks in the Right Manner

7. Homework

8. Promote Student Autonomy

9. Give Support So Students Can Learn at Their Own Pace

10. Consolidate Lessons

11. Give Students Autonomy Over Notes

12. Evaluate Values That Matter Most

13. Bring Students into Formative Assessment

14. Assessment Needs to Connect to an Outcome

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How To Promote Critical Thinking In Your Classroom

Teaching Problem-Solving Skills

Principles for teaching problem solving

Woods’ problem-solving model

Think about it

Plan a solution

Carry out the plan

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Building Thinking Classrooms: Conditions for Problem-Solving

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5 Ways to Encourage Problem-Solving in your Classroom

1. Problem Solve as a Group

2. Explain and Encourage

3. Time and Patience

4. Ask Questions and Reflect

5. Let them Learn

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Number and algebra

Geometry and measure

Probability and statistics

Working mathematically

For younger learners

Advanced mathematics

The Problem-solving Classroom

11 Activities That Promote Critical Thinking In The Class

Importance of Acquiring Critical Thinking Skills

11 Activities that Promote Critical Thinking in the Class

1. Worst Case Scenario

2. If You Build It

4. Keeping it Real