200 Interesting Physics Seminar and Powerpoint Presentation Topics
Interesting topics for Powerpoint Presentation in Physics
- Special Relativity and General Relativity
- Quantum Computing
- Time dilation
- Physics of Babies
- Nikola Tesla Inventions ( PPT2 )
- Greatest Physicists and their contribution
- Physics-Chemistry-Biology Relation
- Physics in Sports Link 2
- Physics in our everyday life
- Newtonian and Non-newtonian fluid
- Anti-Gravity
- Thermodynamics in Everyday Life
- Airborne Wind Energy / Flying Windmills
- Pumped-storage hydroelectricity
- Compressed air energy storage ( PDF )
- Magnetoresistance
- Fusion Power Generation
- Fluid Flow Continuity and Bernoulli’s Equation
- Archimedes' Principle and Its Applications
- Physics of Touch Screens Technology ( Article )
- Exoplanets / Extra-Solar Planets
- Space Telescopes ( Hubble / James Webb Space Telescope )
- Carbon Nanotubes
- The Physics of the Egyptian Pyramids
- Magnus effect and its applications
- Sustainable energy ( PPT 2 )
- The Physics of Fire ( PPT )
- The Motion of the Planets
- Artificial Intelligence (AI) in Our Everyday Life
- The String theory: A theory of Everything
- Electromagnetism and Its applications in daily life
- Electromagnetic Induction
- Electromagnetic Spectrum / Electromagnetic Radiation
- Transformers
- Force sensor
- Friction in our everyday life and Its types ( PPT 2 ) ( PDF )
- Magnetorheological fluid
- Magnetic field due to currents in wires ( PPT 2 )
- Magnetic field patterns
- Earth's Magnetic Field
- Searching for Magnetic Monopoles
- Electricity and Magnetism
- Maglev Trains: Transrapid magnetic lift trains
- Magnetic Levitation
- Microwave Oven: How it works? ( PDF Report )
- Physics Behind the Climate Change ( PDF Report )
- Electromagnets and their uses
- Fresnel's Equations
- Electric Potential
- Working of Motors
- Working of Generators
- Bioelectromagnetism
- Kinematics in our daily lives
- Real-Life Examples of Newton’s First Law (Inertia)
- Zero Energy Buildings
- Lightning Bolt Physics
- Lightning Protection System (Static Electricity)
- Electromagnetic Railguns
- LASERS
- Physics behind fidget spinner
- Hoverboard (Self-balancing scooter)
- Physics of roller coasters
- Physics behind musical instruments
- Physics Behind Bruce Lee's One-Inch Punch!
- Electric Cars
- Gauss’ Law
- Working with simple electrical components
- Current and charge
- Ohm's law and resistance
- Oscilloscope
- String theory
- Resistance effects
- Electrical conduction through gases
- Electrostatic charges
- Van de Graaff generator
- Energy conversion
- Components of motion
- Circular motion
- Weightlessness
- Forced vibrations and resonance
- Momentum in two dimensions
- Simple harmonic motion
- Fiction and Its types
- Friction at the atomic level
- Coulomb model
- Superfluidity
- Transmission Lines
- Peso Electricity
- Atmospheric Optics
- Wireless Electricity
- Models of electric circuits
- Wind Energy
- Solar Power
- Geothermal Energy
- Wave Energy
- Concentrated Solar Energy
- Nuclear Power Generation
- Physics behind the Aurora Borealis
- Plasma Physics
- Particle Detectors, Drift Chambers
- Exponential decay and half-life
- Nuclear Fission
- Nuclear Fusion
- Biogas Plant
- Biomass Energy
- First models of the atom
- Cloud chambers
- Particle Accelerators
- Synchrotron
- Model of the atom
- Light behaving like a particle
- Electrons behaving as waves
- Evidence for the hollow atom
- Nature of ionizing radiations
- Radioactive sources: isotopes and availability
- Acceleration due to gravity
- Radio Waves
- Antenna Theory and Design
- How do Mobile networks work?
- Solar System
- Asteroid Belt Formation
- Satellite Communication
- Possibility of life on Mars
- Mangalyaan (India's Mars Mission)
- Chandrayaan-I (India's Lunar Mission)
- Rocket Technology
- Satellite Launch Vehicles
- SpaceX: Falcon Heavy
- Reusable Rockets
- Space Organisations and their achievements
- Global Navigation Satellite System
- Gravitational force and free fall
- Radar Technologies
- Newtonian fluid
- Pinhole camera and lens camera
- Diffraction of light
- Reflection of light
- Refraction of light
- Radio Telescope
- Formation of Galaxies
- Hubble's Law (Evidence)
- Gravity waves
- Kepler’s laws
- The Copernican revolution
- Magnetic sail
- Planetary motion and gravity
- Big Bang (The Origin)
- Beyond Solar System
- Constellations
- Life on Mars
- Mars Exploration
- Why is Venus So Hot?
- Trans-Neptunian region
- Space-Time Fabric
- Journey of Photons
- Atmospheric pressure
- Einstein's Theory of Relativity
- How do airplanes fly?
- Aerodynamics
- Types of waves
- Young's slits
- Superconductivity
- LED | OLED | MicroLED
- Thermal radiation from the human body
- Thermal expansion of Solid and Liquid
- Concept of density
- Evidence for atoms
- Molecular speed
- Higgs boson
- Chandrashekar limit
- Nuclear Reactors
- Large Hadron Collider
- Quantum Mechanics (Introduction)
- Young's double-slit experiment
- Doppler effect in Sound
- Doppler effect in Light
- Integrated Circuits
- Microprocessors
- Display Technology
- 3D Printing
- Virtual Reality
- Biosensors and Bioelectronics
- Ambient intelligence
- Storage Devices
- Semiconductors
- Fiber-optic communication
- Three Phase Circuit
- Home's electrical system
- Types of Gear and working
- Electric Bill Calculation
- Impulse, Momentum, and Collisions
- Dark Energy (Quantum Vacuum Energy)
- Dark Matter
- Acoustic Levitator
- Electrometer
- Hydroelectricity
- Optical instruments
Interesting Questions for Physics Powerpoint Presentation Ideas
- Why do things move?
- Does everything that goes up come down?
- Why does a bicycle stay upright when it's moving but fall when it stops?
- Why do we wear seatbelts?
- Why doesn’t the moon fall into the earth?
- Why is it tough to walk on ice?
- Why does ice melt?
- Why doesn’t the moon fall?
- What is sound?
- What is light?
- What is lightning?
- What makes rainbows?
- How can a boat make of steel float?
- Why can’t we see air, how do we know that it's there?
- Why are some turns on roads banked?
- What keeps me from falling on the Silly Silo at Adventureland?
- Why do my socks sometimes stick together in the clothes dryer?
- Why do I get a shock after I walk across the carpet room and touch something in winter?
- What’s the deal with magnets? Why do they stick on refrigerators?
- By the way, how do refrigerators and air conditioners work?
- Why can’t I cool my room by keeping the refrigerator door opened?
- Why is it a bad idea to plug my TV, stereo, computer, radio, and hairdryer into the same outlet?
- Where does electricity come from?
- Why doesn’t the electricity leak out of the outlet?
- What do airplanes and curveballs have in common?
- Why do my ears pop when I’m on a plane?
- Why can I see all of myself in a mirror that is half as tall as I am?
- what is the Greenhouse effect?
- what’s the deal with the ozone layer?
- Is climate change real? Are we causing it?
- How do(es) x-rays, microwaves, ultrasound, MRIs, LASERS, and cable TV work.?
- By the way, how does TV work?
- Why does the water in my tub spin in a circle as it goes down the drain? Why does it always spin in the same direction?
- How does soap work?
- Why is the sky blue during the day but red at sunset?
- Are nuclear power plants safe?
- How do they take my temperature by sticking that gadget into my ear?
- Why does the cue ball stop dead when it hits another ball head-on?
- What is a day, month, or year?
- Why does a year on Jupiter last 12 years?
- Are hydrogen fuel cells or hybrid cars the answer to the energy crisis?
- What does it take to make an atomic bomb?
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How to make a scientific presentation
Scientific presentation outlines
Questions to ask yourself before you write your talk, 1. how much time do you have, 2. who will you speak to, 3. what do you want the audience to learn from your talk, step 1: outline your presentation, step 2: plan your presentation slides, step 3: make the presentation slides, slide design, text elements, animations and transitions, step 4: practice your presentation, final thoughts, frequently asked questions about preparing scientific presentations, related articles.
A good scientific presentation achieves three things: you communicate the science clearly, your research leaves a lasting impression on your audience, and you enhance your reputation as a scientist.
But, what is the best way to prepare for a scientific presentation? How do you start writing a talk? What details do you include, and what do you leave out?
It’s tempting to launch into making lots of slides. But, starting with the slides can mean you neglect the narrative of your presentation, resulting in an overly detailed, boring talk.
The key to making an engaging scientific presentation is to prepare the narrative of your talk before beginning to construct your presentation slides. Planning your talk will ensure that you tell a clear, compelling scientific story that will engage the audience.
In this guide, you’ll find everything you need to know to make a good oral scientific presentation, including:
- The different types of oral scientific presentations and how they are delivered;
- How to outline a scientific presentation;
- How to make slides for a scientific presentation.
Our advice results from delving into the literature on writing scientific talks and from our own experiences as scientists in giving and listening to presentations. We provide tips and best practices for giving scientific talks in a separate post.
There are two main types of scientific talks:
- Your talk focuses on a single study . Typically, you tell the story of a single scientific paper. This format is common for short talks at contributed sessions in conferences.
- Your talk describes multiple studies. You tell the story of multiple scientific papers. It is crucial to have a theme that unites the studies, for example, an overarching question or problem statement, with each study representing specific but different variations of the same theme. Typically, PhD defenses, invited seminars, lectures, or talks for a prospective employer (i.e., “job talks”) fall into this category.
➡️ Learn how to prepare an excellent thesis defense
The length of time you are allotted for your talk will determine whether you will discuss a single study or multiple studies, and which details to include in your story.
The background and interests of your audience will determine the narrative direction of your talk, and what devices you will use to get their attention. Will you be speaking to people specializing in your field, or will the audience also contain people from disciplines other than your own? To reach non-specialists, you will need to discuss the broader implications of your study outside your field.
The needs of the audience will also determine what technical details you will include, and the language you will use. For example, an undergraduate audience will have different needs than an audience of seasoned academics. Students will require a more comprehensive overview of background information and explanations of jargon but will need less technical methodological details.
Your goal is to speak to the majority. But, make your talk accessible to the least knowledgeable person in the room.
This is called the thesis statement, or simply the “take-home message”. Having listened to your talk, what message do you want the audience to take away from your presentation? Describe the main idea in one or two sentences. You want this theme to be present throughout your presentation. Again, the thesis statement will depend on the audience and the type of talk you are giving.
Your thesis statement will drive the narrative for your talk. By deciding the take-home message you want to convince the audience of as a result of listening to your talk, you decide how the story of your talk will flow and how you will navigate its twists and turns. The thesis statement tells you the results you need to show, which subsequently tells you the methods or studies you need to describe, which decides the angle you take in your introduction.
➡️ Learn how to write a thesis statement
The goal of your talk is that the audience leaves afterward with a clear understanding of the key take-away message of your research. To achieve that goal, you need to tell a coherent, logical story that conveys your thesis statement throughout the presentation. You can tell your story through careful preparation of your talk.
Preparation of a scientific presentation involves three separate stages: outlining the scientific narrative, preparing slides, and practicing your delivery. Making the slides of your talk without first planning what you are going to say is inefficient.
Here, we provide a 4 step guide to writing your scientific presentation:
- Outline your presentation
- Plan your presentation slides
- Make the presentation slides
- Practice your presentation
Writing an outline helps you consider the key pieces of your talk and how they fit together from the beginning, preventing you from forgetting any important details. It also means you avoid changing the order of your slides multiple times, saving you time.
Plan your talk as discrete sections. In the table below, we describe the sections for a single study talk vs. a talk discussing multiple studies:
The following tips apply when writing the outline of a single study talk. You can easily adapt this framework if you are writing a talk discussing multiple studies.
Introduction: Writing the introduction can be the hardest part of writing a talk. And when giving it, it’s the point where you might be at your most nervous. But preparing a good, concise introduction will settle your nerves.
The introduction tells the audience the story of why you studied your topic. A good introduction succinctly achieves four things, in the following order.
- It gives a broad perspective on the problem or topic for people in the audience who may be outside your discipline (i.e., it explains the big-picture problem motivating your study).
- It describes why you did the study, and why the audience should care.
- It gives a brief indication of how your study addressed the problem and provides the necessary background information that the audience needs to understand your work.
- It indicates what the audience will learn from the talk, and prepares them for what will come next.
A good introduction not only gives the big picture and motivations behind your study but also concisely sets the stage for what the audience will learn from the talk (e.g., the questions your work answers, and/or the hypotheses that your work tests). The end of the introduction will lead to a natural transition to the methods.
Give a broad perspective on the problem. The easiest way to start with the big picture is to think of a hook for the first slide of your presentation. A hook is an opening that gets the audience’s attention and gets them interested in your story. In science, this might take the form of a why, or a how question, or it could be a statement about a major problem or open question in your field. Other examples of hooks include quotes, short anecdotes, or interesting statistics.
Why should the audience care? Next, decide on the angle you are going to take on your hook that links to the thesis of your talk. In other words, you need to set the context, i.e., explain why the audience should care. For example, you may introduce an observation from nature, a pattern in experimental data, or a theory that you want to test. The audience must understand your motivations for the study.
Supplementary details. Once you have established the hook and angle, you need to include supplementary details to support them. For example, you might state your hypothesis. Then go into previous work and the current state of knowledge. Include citations of these studies. If you need to introduce some technical methodological details, theory, or jargon, do it here.
Conclude your introduction. The motivation for the work and background information should set the stage for the conclusion of the introduction, where you describe the goals of your study, and any hypotheses or predictions. Let the audience know what they are going to learn.
Methods: The audience will use your description of the methods to assess the approach you took in your study and to decide whether your findings are credible. Tell the story of your methods in chronological order. Use visuals to describe your methods as much as possible. If you have equations, make sure to take the time to explain them. Decide what methods to include and how you will show them. You need enough detail so that your audience will understand what you did and therefore can evaluate your approach, but avoid including superfluous details that do not support your main idea. You want to avoid the common mistake of including too much data, as the audience can read the paper(s) later.
Results: This is the evidence you present for your thesis. The audience will use the results to evaluate the support for your main idea. Choose the most important and interesting results—those that support your thesis. You don’t need to present all the results from your study (indeed, you most likely won’t have time to present them all). Break down complex results into digestible pieces, e.g., comparisons over multiple slides (more tips in the next section).
Summary: Summarize your main findings. Displaying your main findings through visuals can be effective. Emphasize the new contributions to scientific knowledge that your work makes.
Conclusion: Complete the circle by relating your conclusions to the big picture topic in your introduction—and your hook, if possible. It’s important to describe any alternative explanations for your findings. You might also speculate on future directions arising from your research. The slides that comprise your conclusion do not need to state “conclusion”. Rather, the concluding slide title should be a declarative sentence linking back to the big picture problem and your main idea.
It’s important to end well by planning a strong closure to your talk, after which you will thank the audience. Your closing statement should relate to your thesis, perhaps by stating it differently or memorably. Avoid ending awkwardly by memorizing your closing sentence.
By now, you have an outline of the story of your talk, which you can use to plan your slides. Your slides should complement and enhance what you will say. Use the following steps to prepare your slides.
- Write the slide titles to match your talk outline. These should be clear and informative declarative sentences that succinctly give the main idea of the slide (e.g., don’t use “Methods” as a slide title). Have one major idea per slide. In a YouTube talk on designing effective slides , researcher Michael Alley shows examples of instructive slide titles.
- Decide how you will convey the main idea of the slide (e.g., what figures, photographs, equations, statistics, references, or other elements you will need). The body of the slide should support the slide’s main idea.
- Under each slide title, outline what you want to say, in bullet points.
In sum, for each slide, prepare a title that summarizes its major idea, a list of visual elements, and a summary of the points you will make. Ensure each slide connects to your thesis. If it doesn’t, then you don’t need the slide.
Slides for scientific presentations have three major components: text (including labels and legends), graphics, and equations. Here, we give tips on how to present each of these components.
- Have an informative title slide. Include the names of all coauthors and their affiliations. Include an attractive image relating to your study.
- Make the foreground content of your slides “pop” by using an appropriate background. Slides that have white backgrounds with black text work well for small rooms, whereas slides with black backgrounds and white text are suitable for large rooms.
- The layout of your slides should be simple. Pay attention to how and where you lay the visual and text elements on each slide. It’s tempting to cram information, but you need lots of empty space. Retain space at the sides and bottom of your slides.
- Use sans serif fonts with a font size of at least 20 for text, and up to 40 for slide titles. Citations can be in 14 font and should be included at the bottom of the slide.
- Use bold or italics to emphasize words, not underlines or caps. Keep these effects to a minimum.
- Use concise text . You don’t need full sentences. Convey the essence of your message in as few words as possible. Write down what you’d like to say, and then shorten it for the slide. Remove unnecessary filler words.
- Text blocks should be limited to two lines. This will prevent you from crowding too much information on the slide.
- Include names of technical terms in your talk slides, especially if they are not familiar to everyone in the audience.
- Proofread your slides. Typos and grammatical errors are distracting for your audience.
- Include citations for the hypotheses or observations of other scientists.
- Good figures and graphics are essential to sustain audience interest. Use graphics and photographs to show the experiment or study system in action and to explain abstract concepts.
- Don’t use figures straight from your paper as they may be too detailed for your talk, and details like axes may be too small. Make new versions if necessary. Make them large enough to be visible from the back of the room.
- Use graphs to show your results, not tables. Tables are difficult for your audience to digest! If you must present a table, keep it simple.
- Label the axes of graphs and indicate the units. Label important components of graphics and photographs and include captions. Include sources for graphics that are not your own.
- Explain all the elements of a graph. This includes the axes, what the colors and markers mean, and patterns in the data.
- Use colors in figures and text in a meaningful, not random, way. For example, contrasting colors can be effective for pointing out comparisons and/or differences. Don’t use neon colors or pastels.
- Use thick lines in figures, and use color to create contrasts in the figures you present. Don’t use red/green or red/blue combinations, as color-blind audience members can’t distinguish between them.
- Arrows or circles can be effective for drawing attention to key details in graphs and equations. Add some text annotations along with them.
- Write your summary and conclusion slides using graphics, rather than showing a slide with a list of bullet points. Showing some of your results again can be helpful to remind the audience of your message.
- If your talk has equations, take time to explain them. Include text boxes to explain variables and mathematical terms, and put them under each term in the equation.
- Combine equations with a graphic that shows the scientific principle, or include a diagram of the mathematical model.
- Use animations judiciously. They are helpful to reveal complex ideas gradually, for example, if you need to make a comparison or contrast or to build a complicated argument or figure. For lists, reveal one bullet point at a time. New ideas appearing sequentially will help your audience follow your logic.
- Slide transitions should be simple. Silly ones distract from your message.
- Decide how you will make the transition as you move from one section of your talk to the next. For example, if you spend time talking through details, provide a summary afterward, especially in a long talk. Another common tactic is to have a “home slide” that you return to multiple times during the talk that reinforces your main idea or message. In her YouTube talk on designing effective scientific presentations , Stanford biologist Susan McConnell suggests using the approach of home slides to build a cohesive narrative.
To deliver a polished presentation, it is essential to practice it. Here are some tips.
- For your first run-through, practice alone. Pay attention to your narrative. Does your story flow naturally? Do you know how you will start and end? Are there any awkward transitions? Do animations help you tell your story? Do your slides help to convey what you are saying or are they missing components?
- Next, practice in front of your advisor, and/or your peers (e.g., your lab group). Ask someone to time your talk. Take note of their feedback and the questions that they ask you (you might be asked similar questions during your real talk).
- Edit your talk, taking into account the feedback you’ve received. Eliminate superfluous slides that don’t contribute to your takeaway message.
- Practice as many times as needed to memorize the order of your slides and the key transition points of your talk. However, don’t try to learn your talk word for word. Instead, memorize opening and closing statements, and sentences at key junctures in the presentation. Your presentation should resemble a serious but spontaneous conversation with the audience.
- Practicing multiple times also helps you hone the delivery of your talk. While rehearsing, pay attention to your vocal intonations and speed. Make sure to take pauses while you speak, and make eye contact with your imaginary audience.
- Make sure your talk finishes within the allotted time, and remember to leave time for questions. Conferences are particularly strict on run time.
- Anticipate questions and challenges from the audience, and clarify ambiguities within your slides and/or speech in response.
- If you anticipate that you could be asked questions about details but you don’t have time to include them, or they detract from the main message of your talk, you can prepare slides that address these questions and place them after the final slide of your talk.
➡️ More tips for giving scientific presentations
An organized presentation with a clear narrative will help you communicate your ideas effectively, which is essential for engaging your audience and conveying the importance of your work. Taking time to plan and outline your scientific presentation before writing the slides will help you manage your nerves and feel more confident during the presentation, which will improve your overall performance.
A good scientific presentation has an engaging scientific narrative with a memorable take-home message. It has clear, informative slides that enhance what the speaker says. You need to practice your talk many times to ensure you deliver a polished presentation.
First, consider who will attend your presentation, and what you want the audience to learn about your research. Tailor your content to their level of knowledge and interests. Second, create an outline for your presentation, including the key points you want to make and the evidence you will use to support those points. Finally, practice your presentation several times to ensure that it flows smoothly and that you are comfortable with the material.
Prepare an opening that immediately gets the audience’s attention. A common device is a why or a how question, or a statement of a major open problem in your field, but you could also start with a quote, interesting statistic, or case study from your field.
Scientific presentations typically either focus on a single study (e.g., a 15-minute conference presentation) or tell the story of multiple studies (e.g., a PhD defense or 50-minute conference keynote talk). For a single study talk, the structure follows the scientific paper format: Introduction, Methods, Results, Summary, and Conclusion, whereas the format of a talk discussing multiple studies is more complex, but a theme unifies the studies.
Ensure you have one major idea per slide, and convey that idea clearly (through images, equations, statistics, citations, video, etc.). The slide should include a title that summarizes the major point of the slide, should not contain too much text or too many graphics, and color should be used meaningfully.
Top 101 Physics Topics For Presentation [Updated]
Physics, the science that seeks to understand the fundamental principles governing the universe, offers a vast array of intriguing topics suitable for presentations. From classical mechanics to quantum physics, the realm of physics encompasses a wide range of phenomena that shape our understanding of the natural world. In this blog, we’ll delve into various physics topics for presentations, exploring their significance, applications, and relevance in everyday life.
How to Make Your Physics Presentation?
Table of Contents
Creating a compelling physics presentation involves careful planning, research, and effective communication of complex concepts in a clear and engaging manner. Here are some steps to help you make your physics presentation:
- Choose a Topic: Select a physics topic that interests you and aligns with your audience’s level of understanding. Consider the relevance and significance of the topic and its potential to engage and educate your audience.
- Conduct Research: Research thoroughly using trusted sources like textbooks, scientific journals, and reputable websites to grasp the topic’s key concepts.
- Develop an Outline: Organize your presentation into logical sections or themes. Use the outline provided earlier as a template, adapting it to suit your chosen topic and presentation format.
- Create Visual Aids: Prepare visual aids such as slides, diagrams, and animations to complement your presentation. Use clear and concise graphics to illustrate complex concepts and enhance audience comprehension.
- Craft a Clear Narrative: Structure your presentation with a clear beginning, middle, and end. Start with an attention-grabbing introduction to introduce the topic and establish its relevance. Present the main content in a logical sequence, highlighting key points and supporting evidence. Conclude with a summary of key takeaways and implications.
- Practice Delivery: Rehearse your presentation multiple times to familiarize yourself with the content and refine your delivery. Pay attention to pacing, clarity, and nonverbal communication cues such as posture and gestures.
- Engage Your Audience: Encourage active participation and interaction by asking questions, soliciting feedback, and incorporating interactive elements such as demonstrations or group activities. Tailor your presentation to the interests and background knowledge of your audience to keep them engaged and attentive.
- Anticipate Questions: Prepare for potential questions from your audience by anticipating areas of confusion or ambiguity in your presentation. Be ready to provide clarifications, examples, or references to further resources to address any inquiries.
- Seek Feedback: Solicit feedback from peers, mentors, or colleagues to gain valuable insights into areas for improvement. Consider their suggestions and incorporate constructive criticism to enhance the effectiveness of your presentation.
- Reflect and Iterate: After delivering your presentation, take time to reflect on your performance and the audience’s response. Identify strengths and weaknesses, and consider how you can refine your approach for future presentations.
By following these steps and applying careful planning and preparation, you can create a compelling physics presentation that effectively communicates complex concepts and engages your audience in the wonders of the natural world.
Top 101 Physics Topics For Presentation
- Newton’s Laws of Motion
- Conservation of Energy
- Conservation of Momentum
- Projectile Motion
- Friction: Types and Effects
- Laws of Thermodynamics
- Heat Transfer Mechanisms
- Applications of Thermodynamics
- Electric Fields and Charges
- Magnetic Fields and Forces
- Electromagnetic Induction
- Applications of Electricity and Magnetism
- Reflection and Refraction of Light
- Wave Optics and Interference
- Optical Instruments: Microscopes and Telescopes
- Modern Optical Technologies
- Wave-Particle Duality
- Heisenberg’s Uncertainty Principle
- Quantum Tunneling
- Applications of Quantum Mechanics
- Special Theory of Relativity
- General Theory of Relativity
- Time Dilation and Length Contraction
- Black Holes: Formation and Properties
- Dark Matter and Dark Energy
- Atomic Structure and Spectroscopy
- Radioactivity and Nuclear Reactions
- Nuclear Energy: Pros and Cons
- Nuclear Medicine: Applications and Techniques
- Stars: Formation and Evolution
- Stellar Structure and Dynamics
- Galaxies: Types and Properties
- Cosmology: The Big Bang Theory
- Gravitational Waves: Detection and Significance
- Quantum Gravity: Theoretical Concepts
- String Theory: Basics and Implications
- High Energy Physics: Particle Accelerators
- Standard Model of Particle Physics
- Quantum Field Theory
- Symmetry in Physics
- Chaos Theory: Deterministic Chaos
- Fluid Dynamics: Flow Patterns and Applications
- Aerodynamics: Principles and Applications
- Bernoulli’s Principle
- Newtonian and Non-Newtonian Fluids
- Quantum Computing: Principles and Applications
- Cryptography: Quantum Key Distribution
- Quantum Teleportation
- Quantum Entanglement
- Bose-Einstein Condensate
- Superconductivity: Phenomena and Applications
- Magnetic Levitation: Maglev Trains
- Quantum Dots: Properties and Uses
- Nanotechnology: Applications in Physics
- Carbon Nanotubes: Structure and Properties
- Graphene: Properties and Potential Applications
- Optoelectronics: Devices and Technologies
- Photonics: Light-based Technologies
- Lasers: Principles and Applications
- Holography: 3D Imaging Techniques
- Quantum Sensors: Principles and Applications
- Quantum Metrology: Precision Measurements
- Quantum Biology: Biological Processes from a Quantum Perspective
- Quantum Optics: Manipulation of Light at the Quantum Level
- Quantum Materials: Properties and Potential Applications
- Quantum Algorithms: Computational Advantages of Quantum Computing
- Topological Insulators: Unique Electronic Properties
- Neutrinos: Properties and Detection
- Neutron Stars and Pulsars
- Magnetars: Extremely Magnetic Neutron Stars
- Cosmic Rays: Origins and Effects
- Solar Physics: Sunspots and Solar Flares
- Aurora Borealis and Aurora Australis
- Space Weather: Impact on Earth and Satellites
- Plasma Physics: Properties and Applications
- Fusion Energy: Achievements and Challenges
- Particle Astrophysics: Cosmic Rays and High-Energy Particles
- Quantum Astrophysics: Applying Quantum Mechanics to Cosmological Phenomena
- Exoplanets: Discoveries and Characterization
- Astrobiology: Search for Extraterrestrial Life
- Cosmic Microwave Background Radiation
- Black Hole Thermodynamics
- Gravitational Lensing: Observational Effects
- Multiverse Theory: Theoretical Implications of Cosmology
- Quantum Consciousness: Theoretical Considerations
- Quantum Gravity: Unifying Quantum Mechanics and General Relativity
- Quantum Cosmology: Cosmological Models Based on Quantum Theory
- Quantum Field Theory: Foundations and Applications in Particle Physics
- Quantum Gravity: Approaches and Challenges
- Quantum Chromodynamics: Theory of Strong Interactions
- Quantum Electrodynamics: Theory of Electromagnetic Interactions
- Quantum Spin: Properties and Applications
- Quantum Hall Effect: Topological Phenomenon in Condensed Matter Physics
- Quantum Phase Transitions: Critical Phenomena in Quantum Systems
- Quantum Computing: Architectures and Algorithms
- Quantum Communication: Secure Communication Based on Quantum Principles
- Quantum Simulation: Modeling Complex Quantum Systems
- Quantum Cryptography : Secure Communication Using Quantum Key Distribution
- Quantum Sensing: Ultra-Precise Measurement Techniques
- Quantum Metrology: Achieving High Precision with Quantum Techniques
- Quantum Technologies: Emerging Applications of Quantum Physics
Tips to Fellow to Make Physics Presentation Successful
Making a physics presentation successful requires careful planning, effective communication, and engaging presentation skills. Here are some tips to help your fellow make their physics presentation successful:
- Know Your Audience: Understand the background knowledge and interests of your audience to tailor your presentation accordingly. Adjust the level of technical detail and terminology to ensure clarity and engagement.
- Define Clear Objectives: Clearly define the objectives of your presentation, outlining what you aim to achieve and the key points you intend to convey. This will help you stay focused and ensure that your presentation delivers a coherent message.
- Organize Your Content: Structure your presentation in a logical manner, with a clear introduction, main body, and conclusion. Use headings, subheadings, and bullet points to organize your content and guide the audience through your presentation.
- Use Visual Aids Wisely: Incorporate visual aids such as slides, diagrams, and animations to enhance understanding and retention of key concepts. Keep visual elements clear, concise, and relevant to the content of your presentation.
- Practice Delivery: Rehearse your presentation multiple times to familiarize yourself with the content and refine your delivery. Pay attention to pacing, tone of voice, and body language to ensure confident and engaging presentation delivery.
- Engage Your Audience: Encourage active participation and interaction by asking questions, soliciting feedback, and incorporating interactive elements such as demonstrations or group activities. Engage with your audience to maintain their interest and attention throughout your presentation.
- Clarify Complex Concepts: Break down complex concepts into simpler, more understandable terms, using analogies, examples, and real-world applications to illustrate key points. Clarify any technical jargon or terminology to ensure that all audience members can follow along.
- Be Prepared for Questions: Anticipate questions from your audience and prepare thoughtful responses in advance. Be open to feedback and willing to address any uncertainties or misconceptions that may arise during the Q&A session.
- Demonstrate Enthusiasm: Convey your passion and enthusiasm for the subject matter through your presentation delivery. Demonstrate genuine interest and excitement in sharing your knowledge with your audience, inspiring curiosity and engagement.
- Seek Feedback: After delivering your presentation, solicit feedback from your audience and peers to gain valuable insights into areas for improvement. Reflect on their input and incorporate constructive criticism to enhance the effectiveness of your future presentations.
Physics is fascinating! It’s like a colorful quilt filled with amazing ideas and things that make us wonder about the universe. Whether we’re talking about basic stuff like how things move or super cool things like quantum mechanics, physics presentations help us understand how the world works. They show us the important rules that make everything tick, from tiny atoms to huge galaxies.
By learning about physics, we can see how clever humans are in figuring out nature’s secrets and using them to make awesome technology. It’s like unlocking a treasure chest full of wonders and surprises!
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Physics Presentation templates
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Math Subject for Pre-K: Shapes
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Science Subject for Middle School - 6th Grade: Physics I
If you understand physics, you understand how the world works! Prepare a fun lesson where your students will understand the basics of physics: from Newton’s laws to fluid dynamics, accelerations, movement, and reactions... all in a visual and fun way. Editing these slides will turn to a fun experiment if...
Energy and Waves - Physics - 11th Grade
Download the Energy and Waves - Physics - 11th Grade presentation for PowerPoint or Google Slides. High school students are approaching adulthood, and therefore, this template’s design reflects the mature nature of their education. Customize the well-defined sections, integrate multimedia and interactive elements and allow space for research or group...
Static Electricity Lesson for Elementary
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Science Subject for Elementary - 2nd Grade: Physics
So if you drop a bowling ball and a feather from a skyscraper, they hit the ground at the same time? That can’t be true, right? Explain your little students how physics work with this beautiful template for Google Slides and PowerPoint, the design is completely editable and includes resources...
Physical Science - Physics - 7th Grade
Ignite the scientific curiosity in your 7th grade students with this comprehensive Google Slides and PowerPoint template. Styled in a cheerful yellow, this fun and illustrated template is guaranteed to guide your students through the fascinating world of physics. Get ready to unveil the laws of physics, with the plethora...
Science Subject for Elementary - 2nd Grade: Science Fair
It's scientifically proven that science classes are among the most popular in schools. Some even hold science fairs, giving kids the chance to show & tell their own experiments and inventions. If you need to create a presentation about this, put your brain to work because this template is made...
Force, Motion, and Energy - Science - 11th Grade
For as long as we are people, we live in a physical world. Things move, slide, collide, get warmer or colder, accelerate... From the laws of motion to the concept of potential and kinetic energy, our comprehensive template allows you to explore these concepts in an engaging and interactive way....
Waves and Optics - Science - 10th Grade
Download the Waves and Optics - Science - 10th Grade presentation for PowerPoint or Google Slides. High school students are approaching adulthood, and therefore, this template’s design reflects the mature nature of their education. Customize the well-defined sections, integrate multimedia and interactive elements and allow space for research or group...
Operations and Algebraic Thinking - Math for Elementary
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Download the Physical Sciences - Science - 6th Grade presentation for PowerPoint or Google Slides. If you’re looking for a way to motivate and engage students who are undergoing significant physical, social, and emotional development, then you can’t go wrong with an educational template designed for Middle School by Slidesgo!...
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The Physics of Sailing
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Biophysics Specialized Academy
Download the Biophysics Specialized Academy presentation for PowerPoint or Google Slides. Are you looking for a way to make your school academy stand out among the competition? This template is designed to showcase all the fantastic aspects of your center. With perfect slides that allow you to easily add information...
Physicist CV
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Science Subject for Middle School - 6th Grade: Physics II
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Physics for Middle School Infographics
Download the Physics for Middle School Infographics template for PowerPoint or Google Slides and discover the power of infographics. An infographic resource gives you the ability to showcase your content in a more visual way, which will make it easier for your audience to understand your topic. Slidesgo infographics like...
Newton's Laws Infographics
Newton was a scientist that changed the history of physics. He came up with three laws that could describe how the objects around us move and interact with each other, and they’re super easy to understand, as long as you use visual representations of the forces. This template offers exactly...
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Papers and Presentations
Ouellette, E., Lewsirirat, S., Biju Sebastian, R., Lundsgaard, M., Krist, C., & Kuo, E. (2023, July 19-20). Alignment between student epistemological views and experiences with course structures in introductory physics: A Case Study. In D. Jones, Q. X. Ryan, and A. Pawl (Eds.), 2023 Physics Education Research Conference, Sacramento, CA, July 19-20, 2023 (pp. 260-265).
Adlakha, V. & Kuo, E. (2023). Applying Causal Inference Principles to the Analysis of Observational Studies in Physics Education Research. Physical Review Physics Education Research, 19, 020160.
Boden, K., Kuo, E., Nokes-Malach, T.J., Wallace, T., & Menekse, M. (2023). Investigating the Predictive Relations Between Self-efficacy and Achievement Goals on Procedural and Conceptual Science Learning. Journal of Educational Research , 116(5), 241-253.
Presentations at the 2023 American Association of Physics Teachers Summer Meeting and Physics Education Research Conference, Sacramento CA, July 16-20 2023.
Presentations at the 2023 American Physical Society April Meeting, Minneapolis, MN, April 15 - 18, 2023.
Kuo, E. (2023). Two Perspectives on Physics Problem Solving and Their Relation to Adaptive Expertise. In M. F. Taşar and P. R. L. Heron (Eds.), The International Handbook of Physics Education Research: Learning Physics (pp. 10-1 to 10-26). AIP Publishing.
Presentations at the 2022 American Association of Physics Teachers Summer Meeting and Physics Education Research Conference, Grand Rapids, MI, July 9 - 13, 2022.
Presentations at the 2022 American Physical Society April Meeting, New York, NY, April 9 - 12, 2022.
G. Ehrlich, K. Gifford, E. Kuo, and E. Bumbacher, Seeking physical/mathematical coherence by recruiting and reconciling reasoning: A case study in E&M, in Proceedings of the 2021 Physics Education Research Conference , online, edited by M.B. Bennett, B.W. Frank, and R.E. Vieyra (2021), p. 111.
K. Gifford, G. Ehrlich, E. Bumbacher, and E. Kuo, Seeking coherence and switching reasoning after forgetting an equation, in Proceedings of the 2021 Physics Education Research Conference , online, edited by M.B. Bennett, B.W. Frank, and R.E. Vieyra (2021), p. 154.
S. Jaramillo, E. Kuo, B. Rottman, and T. Nokes-Malach, Investigating causal inference difficulties with a simple, qualitative force-and-motion problem, in Proceedings of the 2021 Physics Education Research Conference , online, edited by M.B. Bennett, B.W. Frank, and R.E. Vieyra (2021), p. 197.
Presentations at the 2021 American Association of Physics Teachers Summer Meeting and Physics Education Research Conference, online, July 31 - August 5, 2021.
J. W. Morphew, E. Kuo, Q. King-Shepard, R. Lin, P. Kwon, T. J. Nokes-Malach, and J. P. Mestre, Seeing and Doing Are Not Believing: Investigating When and How Conceptual Knowledge Impinges on Observation and Recall of Physical Motion, Journal of Experimental Psychology: Applied 27, 307 (2021).
E. Kuo, M. M. Hull, A. Elby, and A. Gupta, Assessing Mathematical Sensemaking in Physics through Calculation-Concept Crossover, Phys. Rev. Phys. Educ. Res. 16, 020109 (2020).
Presentations at the 2020 American Association of Physics Teachers Summer Meeting and Physics Education Research Conference, online, July 19-23, 2020.
E. Kuo, N.K. Weinlader, B.M. Rottman, and T.J. Nokes-Malach, Using causal networks to examine resource productivity and coordination in learning science, in The Interdisciplinary of the Learning Sciences, 14th International Conference of the Learning Sciences (ICLS) 2020, Volume 2., Nashville, Tennessee , edited by M. Gresalfi and I. S. Horn (2020), p. 875.
K. Ansell "Cultivating adaptive expertise in the introductory physics laboratory"
Effect of presentation style and problem-solving attempts on metacognition and learning from solution videos. Jason W. Morphew, Gary E. Gladding, and Jose P. Mestre, Phys. Rev. Phys. Educ. Res. 16 , 010104 (2020)
Zhang, M, A. Engel, T. Stelzer, and J. Morphew. "Effect of online practice exams on student performance." Paper presented at the Physics Education Research Conference 2019, Provo, UT, July 24-25, 2019.
B. Gutmann "Tools for underprepared students in engineering physics with a focus on online mastery learning exercises"
Presentations made by the Illinois PER group at the 2019 American Association of Physics Teachers Summer Meeting and Physics Education Research Conference, held in Provo, UT July 20-25.
B. Gutmann, N. Schroeder, and T. Stelzer, Effective Grain-Size of Mastery-Style Online Homework Levels, presented at the Physics Education Research Conference 2018, Washington, DC, 2018, .
G. Ehrlich and M. Selen, "Eureka!" "That's funny...": Problematization and value in two classroom epiphanies, presented at the Physics Education Research Conference 2018, Washington, DC, 2018, .
Presentations made by the Illinois PER group at the 2018 American Association of Physics Teachers Summer Meeting and Physics Education Research Conference, held in Washington, DC July 28-August 2.
Brianne Gutmann, Gary Gladding, Morten Lundsgaard, and Timothy Stelzer Phys. Rev. Phys. Educ. Res. 14 , 010128 – Published 18 May 2018
Presentations given at the 2018 American Association of Physics Teachers Winter Meeting, held in San Diego, CA, January 6-9.
William R. Evans and Mats A. Selen Phys. Rev. Phys. Educ. Res. 13 , 020119 (2017) - Published 4 October 2017
Poster presented at the 2017 Physics Education Research Conference (PERC) describing the effects of lesson design on the choices students make while doing at-home physics experiments.
Poster presented at the Foundations and Frontiers in Physics Education Research (FFPER) 2017 conference describing effects of skills-focused lab instruction on student data analysis strategies and the conclusions they reach.
K. Ansell and M. Selen, Student attitudes in a new hybrid design-based introductory physics laboratory, presented at the Physics Education Research Conference 2016, Sacramento, CA, 2016, <https://www.compadre.org/Repository/document/ServeFile.cfm?ID=14188&DocID=4540>.
Poster presented at the 2016 Physics Education Research Conference describing laboratory reform efforts in introductory calculus-based mechanics and some preliminary results.
This is a supplemental information page for the research I am presenting at the 2015 AAPT Summer Meeting regarding clinical studies investigating the use of mastery-style online homework in introductory physics classes.
Poster presented at the 2015 Physics Education Research Conference describing a clinical study probing the effectiveness of describing before exploring vs exploring before describing as physics instructional methods.
Landing page for Noah's 2015 Poster Supplements
Selen, M. A., Stelzer, T. J. (2008) U.S. Patent CA 2576495 A1 . Washington, D.C.: U.S. Patent and Trademark Office
N. Schroeder, G. Gladding, B. Gutmann, and T. Stelzer. "Narrated animated solution videos in a mastery setting", Phys.Rev. ST Phys. Educ. Res. 11, 010103. (2015)
W. Fakcharoenphol and T. Stelzer "Physics exam preparation: A comparison of three methods" Phys. Rev. ST Phys. Educ. Res. 10, 010108 (2014)
**Nokes-Malach, T.J. & Mestre, J.P. (2013). Educational Psychologist , 48 (#3) 184-207.
Henderson, C., Barthelemy, R., Finkelstein, N. D., & Mestre, J. P. (2012). Physics Education Research funding census. In N. S. Rebello, P. V. Engelhardt, & C. Singh (Eds.), Proceedings of the 2011 Physics Education Research Conference (pp. 211-214). Melville NY: American Institute of Physics. doi:10.1063/1.3680032.
Docktor, J.L, Mestre, J.P. & Ross, B.H. (2012). Physical Review-Special Topics: Physics Education Research, 8 (#2) 020102 (11 pages).
Christianson, K., Mestre, J.P., & Luke, S.G. (2012). Applied Cognitive Psychology, 26 , 810-822.
Mestre, J.P. & Ross, B.H. (Eds.). (Academic Press: San Diego CA) 313 pages (2011).
Torigoe, E.T.; Gladding, G.E.. American Journal of Physics, v 79, n 1, p 133-40, Jan. 2011
Phys. Rev. ST Physics Ed. Research 7, 010107 (2011)
T. Stelzer, D. Brookes, G. Gladding, and, J. Mestre. "Impact of multimedia learning module on an introductory course on electricity and magnetism," American Journal of Physics 78 755 (2010).
Physical Review Special Topics: Physics Education
Journal of the Learning Sciences, 19(#4), 480-505
Physical Review Special Topics - Physics Education
T. Stelzer, G. Gladding, J. Mestre and D. Brookes. "Comparing the efficacy of multimedia modules with traditional textbooks for the learning of introductory physics content," American Journal of Physics 77 184 (2009)
American Association of Physics Teachers Summer Conference
April APS Meeting St. Louis, MO
AAPT Summer Meeting, Greensboro, NC
2007 Physics Education Research Conference, AIP Conf. Proceedings
7 th International Conference of the Learning Sciences, Indiana University, Bloomington, IN
AAPT Summer Meeting: Syracuse, NY
Phys. Rev. ST Phys. Educ. Res. 2, 020107
2006 Physics Education Research Conference, AIP Conf. Proceedings
Phys. Rev. ST Phys. Educ. Res. 2, 020102
Systemic Changes in Teaching at Leading Research Universities, AAPT, College Park, MD
AAPT Meeting, Salt Lake City, UT, August 2005 (Contributed Talk)
AAPT Meeting, Salt Lake City, UT, (Invited Talk)
APS Forum on Education Fall Newsletter
(393 pages). Greenwich, CT: Information Age Publishing
In J. Mestre (Ed.), Transfer of Learning from a Modern Multidisciplinary Perspective (pp. 155-215). Greenwich, CT: Information Age Publishing
In J. Mestre (Ed.), Transfer of Learning from a Modern Multidisciplinary Perspective (pp. vii-xxvi). Greenwich, CT: Information Age Publishing
In J.M Royer (Ed.) The Cognitive Revolution in Educational Psychology (pp. 119-164). Greenwich, CT: Information Age Publishing
Peer Review, 7(#2, Winter Issue), 24-27
Proceedings of the 2004 Physics Education Research Conference, Sacramento, CA
University of Florida, Gainesville, FL, November 2004 (Colloquium)
University of Wisconsin, Madison, WI, October 2004 (Seminar)
International Society for the Scholarship of Teaching and Learning, Bloomington, IN, October 2004 (Contributed Talk)
AAPT Meeting, Sacramento, CA, August 2004 (Contributed Talk)
ISAAPT Spring Meeting, Urbana, IL, April 2004 (Contributed Talk)
Proceedings of the 2003 Physics Education Research Conference, Madison, WI. Melville, NY: American Institute of Physics
In E. Redish & M. Vicentini (Eds.), Proceedings of the International School of Physics �Enrico Fermi�, Course CLVI, Research on Physics Education (pp. 367-408). Amsterdam: IOS Press
SENCER Backgrounder (published online)see: http://www.sencer.net/pdfs/Backgrounders/ImplicationsofLearningResearchforTeachingScience.pdf
University of Washington, Seattle, WA, Spring 2004 (Seminar)
University of Illinois
Physics Course Conference, Arlington, VA November 2003 (Invited Talk)
AAPT Meeting, Madison, WI, August 2003 (Contributed Talk)
AAPT Meeting, Madison, WI, August 2003 (Invited Talk)
(225 pages). Boston, MA: Allyn & Bacon
(431 pp.). Dubuque, IA: Kendall/Hunt Publishing
AAPT Meeting, Austin, TX, January 2003 (Contributed Talk)
AAPT Meeting, Austin, TX, January 2003 (Invited Talk)
National Science Foundation Report #NSF03-212. 27 pages
Cottrell Scholar Conference, Tucson, AZ, July 2002
(404 pp.). Dubuque, IA: Kendall/Hunt Publishing
Journal of Computers in Mathematics and Science Teaching, 21(3), 229-251
In R.W. Bybee (Ed.), Learning Science and the Science of Learning (pp. 13-22). Arlington, VA: National Science Teachers Association
Journal of Applied Developmental Psychology, 23, 9-50
Forum on Education of the Am. Phys. Soc., 7-8 (Fall 2001)
Industrial Physics Forum
(252 pp.). Dubuque, IA: Kendall/Hunt Publishing
Physics Education, 36, #1, 44-51
Vol. 21, #1. (135 pp.)
(173 pp.). Dubuque, IA: Kendall/Hunt Publishing
(458 pp.). Dubuque, IA: Kendall/Hunt Publishing
(207 pp.). Dubuque, IA: Kendall/Hunt Publishing
In G. Buck, J. Hehn, & D. Leslie-Palecky (Eds.), The Role of Physics Departments in Preparing K-12 Teachers (pp. 109-129). College Park, MD: American Institute of Physics
Journal of Applied Developmental Psychology, 21, 1-11
In R. Lesh, R. & A. Kelly, (Eds.), Handbook of Research Methodologies for Science and Mathematics Education (pp. 151-168). Hillsdale, NJ: Lawrence Erlbaum Associates
(380 pp.). Dubuque, IA: Kendall/Hunt Publishing
(224 pp.). Dubuque, IA: Kendall/Hunt Publishing
(372 pp.). Dubuque, IA: Kendall/Hunt Publishing
(345 pp.). Dubuque, IA: Kendall/Hunt Publishing
(190 pp.). Dubuque, IA: Kendall/Hunt Publishing
Forum on Education of the Am. Phys. Soc., 9-11 (Summer 1997)
In E.F. Redish & J.S. Rigden (Eds.), The Changing Role of Physics Departments in Modern Universities: Proceedings of International Conference on Undergraduate Physics Education (pp. 1019-1036). Woodbury, NY: American Institute of Physics
In A. McNeal and C. D�Avanzo (Eds.), Student-Active Science: Models of Innovation in College Science Teaching (pp. 431-452). Orlando, FL: Saunders College Publishing
American Journal of Physics, 64, 1495-1503
Cognition & Instruction, 14, 373-408
Journal of Computing in Higher Education, 7, 3-47
International Journal of Science Education, 17, 255-269
In S.J. Fitzsimmons & L.C. Kerpelman (Eds.), Teacher Enhancement for Elementary and Secondary Science and Mathematics: Status, Issues and Problems (pp. 3i-3iv). Washington, D.C.: National Science Foundation (NSF 94-80)
In S.J. Fitzsimmons & L.C. Kerpelman (Eds.), Teacher Enhancement for Elementary and Secondary Science and Mathematics: Status, Issues and Problems (pp. 3-1 - 3-53). Washington, D.C.: National Science Foundation (NSF 94-80)
Proceedings of the National Science Foundation Workshop on the Role of Faculty from the Scientific Disciplines in the Undergraduate Education of Future Science and Mathematics Teachers (pp. 120-123). Washington, DC: NSF. (NSF 93-108)
Proceedings of the National Science Foundation Workshop on the Role of Faculty from the Scientific Disciplines in the Undergraduate Education of Future Science and Mathematics Teachers (pp. 139-143). Washington, DC: NSF. (NSF 93-108)
Journal of Research in Science Teaching, 30, 303-317
Journal of the Learning Sciences, 1992, Vol. 2, No. 3, Pages 307-331
In D. Halpern (Ed.), Enhancing Thinking Skills in the Sciences and Mathematics (pp. 77-94). Hillsdale, NJ: Lawrence Erlbaum Association
In G. Keller, R. Magallan, & J. Deneen (Eds.), Assessment and Access for Hispanics in Higher Education (pp. 39-66). Albany, NY: The State University of New York Press
Physics Today, 44, #9 (Sept.), 56-62
Second Edition. NY, NY: The College Board
In M. White & J. Goldsmith (Eds.), Standards and Review Manual: Handbook of Theory and Practice in Knowledge Engineering (pp. 502-520). Kensington, MD: Systemsware
Journal of Educational Psychology, 1989 Dec Vol 81(4) 547-557
The Physics Teacher, 27, 447-456
Memory & Cognition, 17, 627-638
In D. Crowell, V. Kobayashi & D. Topping (Eds.), Thinking Across Cultures: The Third International Conference on Thinking (pp. 455-466). Hillsdale, NJ: Lawrence Erlbaum Associates
Hillsdale, NJ: Lawrence Erlbaum Associates
In R. Barojas (Ed.), AIP Conference Proceedings 173: Cooperative Networks in Physics Education (pp. 109-114). New York, NY: American Institute of Physics
Proceedings of the Tenth Annual Conference of the Cognitive Science Society (pp. 312-318). Hillsdale, NJ: Lawrence Erlbaum Associates
The Ideas of Algebra, K-12: 1988 Yearbook of the National Council of Teachers of Mathematics (127-135). Reston, VA: NCTM
Journal of the National Association for Bilingual Education, 12, 243-279
In R.R. Cocking and J.P. Mestre (Eds.), Linguistic and Cultural Influences on Learning Mathematics (pp. 201-220). Hillsdale, NJ: Lawrence Erlbaum Associates
In R.R. Cocking and J.P. Mestre (Eds.), Linguistic and Cultural Influences on Learning Mathematics (pp. 3-16). Hillsdale, NJ: Lawrence Erlbaum Associates
Browse Course Material
Course info.
- Prof. Markus Klute
Departments
As taught in.
- Nuclear Physics
- Particle Physics
Learning Resource Types
Introduction to nuclear and particle physics, assignments, problem sets, paper presentation.
Below is a list of seminal papers in nuclear and particle physics. You are asked to form a team of two and pick a paper (first come first served). Please review the paper and prepare a 20-minute presentation summarizing the paper and also setting it into context. You can also suggest a paper not listed below.
Parity Violation
Experimental Test of Parity Conservation in Beta Decays
CP Violation
Evidence for the \(2\pi\) Decays of the \(K_2^0\) Meson
Observation of Single Isolated Electrons of High Transverse Momentum in Events with Missing Transverse Energy at the CERN pp Collider
Experimental Observation of Lepton Pairs of Invariant Mass around 95 GeV/c 2 at the CERN SPS Collider
Neutrino Oscillations
Evidence for Oscillation of Atmospheric Neutrinos
Higgs Boson
Observation of a New Boson at a Mass of 125 GeV with the CMS Experiment at the LHC
Observation of a New Particle in the Search for the Standard Model Higgs Boson with the ATLAS Detector at the LHC
Possible Existence of a Neutron
Fermi’s Theory of Beta Decay
Fermi’s Theory of Beta Decay (PDF)
You are leaving MIT OpenCourseWare
EP 446: Solid State Physics: Presenting
- Books + eBooks
- Sources + Literature Review
- Journals + Databases
- AIP Citations
Giving a Presentation
Here are a few tools and suggestions to help prepare you for getting up and presenting in front of a class. Hopefully, you'll be inspired to improve upon the traditional PowerPoint slideshow and integrate technology into your presentations.
Check out these articles for more advice on crafting an engaging and effective presentation:
- Designing Effective Virtual Presentations by KU Online
- What it Takes to Give a Great Presentation
- 1 0 Tips for Improving Your Public Speaking Skills
- Six Tips for Giving a Fabulous Academic Presentation
- 12 Reasons Your Presentation Sucks and How to Fix It
- 16 Useful Tips to Overcome Your Fear of Public Speaking
Sharing Your Presentation
Slideshare allows you to share presentations online. Slides are uploaded to Slideshare, searchable, and able to be shared or embedded across the internet.
Speaker Deck is another option for sharing your presentations online. It is similar to the style of Slideshare, but is ad free. Also, when you embed slideshows, they will automatically resize to the size of the space in which they are being embedded.
Library Resources
PowerPoint , one piece of the Microsoft Office Suite, is perhaps the best known tool for creating presentations. While everyone has seen dry presentations consisting primarily of text on slides, PowerPoint can do much more than this, including offering embedded content such as images, videos, audio files and even dynamic content from the internet.
These tools will help you to do more with your PowerPoint slides.
- 21 PowerPoint Add-ins and Plugins
- PowerPoint Twitter Tools These free tools allow users to interact with their audience via Twitter while presenting. You can poll the audience, take questions and feedback or auto-tweet your presentation all using these Twitter add-ons.
Prezi allows users to create dynamic "zooming" presentations. If you have already created a PowerPoint presentation, it also offers an option to import your existing slides to Prezi. Presentations are created, stored and delivered online.
Prezi offers a large number of tutorials to help you with every step of the process on their YouTube channel . The video below shows how to get started. You can also find examples of Prezis in their gallery .
Emaze is an online presentation platform built on HTML5 technology. Users can create, manage and share their presentations from any browser or mobile device. Emaze offers a variety of templates including formats using 3D animations and video backgrounds. Browse their gallery or view the sample presentation below:
Google Slides
Google Slides is to PowerPoint what Google Docs is to Word. It allows users with a free Google Drive account to create quick and easy presentations. While it doesn't have quite as many features as PowerPoint or others, it makes collaboration simple and works well for basic presentations. Google has a great tutorial to walk you through its features or you can watch the video below.
Thanks to Harvard Law School Library for inspiration in creating this LibGuide.
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284. Electrolyte-assisted polarization leading to enhanced charge separation and solar-to-hydrogen conversion efficiency of seawater splitting Yiyang Li, Hui Zhou, Songhua Cai, Dharmalingam Prabhakaran, Wentian Niu, Alexander Large, Georg Held, Robert A. Taylor, Xin-Ping Wu, and Shik Chi Edman Tsang Nature Catalysis, 2024. DOI: https://doi.org/10.1038/s41929-023-01069-1
283. Stability of Mixed Lead Halide Perovskite Films Encapsulated in Cyclic Olefin Copolymer at Room and Cryogenic Temperatures Mutibah Alanazi, Ashley Marshall, Shaoni Kar, Jinwoo Kim, Yincheng Liu, Henry Snaith, Robert A. Taylor, and Tristan Farrow J. Phys. Chem. Lett., 14 , 11333-11341, 2023. DOI: https://doi.org/10.1021/acs.jpclett.3c02733
282. Ultranarrow linewidth room-temperature single-photon source from perovskite quantum dot embedded in optical microcavity Tristan Farrow, Amit R. Dhawan, Ashley Marshall, Alex Ghorbal, Wonmin Son, Henry J. Snaith, Jason M. Smith, and Robert A. Taylor Nano Letters, 23 , 10667, 2023. DOI: https://doi.org/10.1021/acs.nanolett.3c02058
281. Gain enhancement of perovskite nanosheets by a patterned waveguide: excitation and temperature dependence of gain saturation Robert Taylor, Inhong Kim, Ga Eul Choi, Ming Mei, Min Woo Kim, Minju Kim, Young Woo Kwon, Tae-In Jeong, Seungchul Kim, Suck Won Hong, and Kwangseuk Kyhm Light:Science & Applications, 12 , 285, 2023. DOI: https://doi.org/10.1038/s41377-023-01313-0
280. Piezoelectric Energy Harvesting Using Solar Radiation Pressure Enhanced by Surface Plasmons at Visible to Near-infrared Wavelengths Jae-Hoon Ryu, Ha Young Lee, Sung-Hyun Kim, Jeong-Yeon Lee, Jun-Hyeon Jang, Hyung Soo Ahn, Sun-Lyeong Hwang, Robert A. Taylor, Dong Han Ha and Sam Nyung Yi Sol. RRL, 2300039, 2023. DOI: https://doi.org/10.1002/solr.202300039
279. Reducing Nonradiative Losses in Perovskite LEDs Through Atomic Layer Deposition of A l2 O 3 on the Hole-injection Contact Emil G. Dyrvik, Jonathan H. Warby, Melissa M. McCarthy, Alexandra J. Ramadan, Karl-Augustin Zaininger, Andreas E. Lauritzen, Suhas Mahesh, Robert A. Taylor, Henry J. Snaith ACS Nano, 17 , 3289, 2023. DOI: https://doi.org/10.1021/acsnano.2c04786
278. Optical gain of vertically-coupled Cd0.6Zn0.4Te/ZnTe quantum dots Ming Mei, Minju Kim, Minwoo Kim, Inhong Kim, Hong Seok Lee, Robert A. Taylor, and Kwangseuk Kyhm Nanomaterials, 13 , 716, 2023. DOI: https://doi.org/10.3390/nano13040716
277. Three-photon excitation of InGaN quantum dots Viviana Villafane, Bianca Scaparra, Manuel Rieger, Stefan Appel, Rahul Trivedi, Tongtong Zhu, John Jarman, Rachel A. Oliver, Robert A. Taylor, Jonathan J. Finley, and Kai Muller Physical Review Letters, 130 , 083602, 2023. DOI: https://doi.org/10.1103/PhysRevLett.130.083602
276. Molecular Layer-by-layer Re-stacking of MoS 2 -In 2 Se 3 by Electrostatic means: Assembly of a New Layered Photocatalyst Bryan K Y Ng, Cherie C Y Wong, Wentian Niu, Hector P Garcia, Yiyang Li, Ping-Luen Ho, Winson C H Kuo, Robert A Taylor, Keita Taniya, Qi Wei, Mingjie Li, Michail Stamatakis, Shik Chi Edman Tsang Materials Chemistry Frontiers, 2023. DOI: https://doi.org/10.1039/D2QM01095J
275. Direct current piezoelectric energy harvesting based on plasmon-enhanced solar radiation pressure Ha Young Lee, Min Sub Kwak, Geon-Tae Hwang, Hyung Soo Ahn, Robert A. Taylor, Dong Han Ha & Sam Nyung Yi Advanced Optical Materials, 2202212, 2023. DOI: https://doi.org/10.1002/adom.202202212
274. Elliptical polarisation of localized states in an anisotropic single GaAs quantum ring Seongho Park, Minju Kim, Inhong Kim, Robert A. Taylor, Jindong Song and Kwangseuk Kyhm Nanomaterials, 13 , 184, 2022. DOI: https://doi.org/10.3390/nano13010184
273. Design of free-space couplers for suspended triangular nano-beam waveguides J.P. Hadden, Cobi Maynard, Daryl M. Beggs, Robert A. Taylor and Anthony J. Bennett J. Phys. D: Appl. Phys., 55 , 474002, 2022. DOI: https://doi.org//10.1088/1361-6463/ac941e
272. Single-photon generation through cavity-STIRAP in a neutral QD embedded in a micropillar cavity: an FDTD model study Gaby M. Slavcheva, Mirella V. Koleva, Kai Müller, Robert A. Taylor Proceedings Volume 12243, Photonics for Quantum 2022; 122430E, 2022. DOI: https://doi.org/10.1117/12.2635200
271. Conformation control of triplet state diffusion in platinum containing polyfluorene copolymers Nikol T. Lambeva, Claudius C. Mullen, Xuyu Gao, Qingjing Wu, Robert A. Taylor, Youtian Tao, Donal D. C. Bradley Journal of Polymer Science, 1-11, 2022. DOI: https://doi.org/10.1002/pol.20220366
270. Self-assembly of perovskite nanocrystals. Atanu Jana, Abhishek Meena, Supriya A. Patil, Yongcheol Jo , Sangeun Cho, Youngsin Park, Vijaya Gopalan Sree, Hyungsang Kim, Hyunsik Im, Robert A. Taylor Progress in Materials Science, 129 , 100975, 2022. DOI: https://doi.org/10.1016/j.pmatsci.2022.100975
269. Strain Tunable Optical Microlens Arrays with Deformable Wrinkles for Spatially Coordinated Image Projection on a Security Substrate Suck Won Hong, In Sik Choi, Seongho Park, Jeon Sangheon, Young Woo Kwon, Rowoon Park, Robert A. Taylor, and Kwangseuk Kyhm Microsystems and Nanoengineering, 8 :98, 2022. DOI: https://doi.org/10.1038/s41378-022-00399-7
268. Perovskite: scintillators, direct detectors, and X-ray imagers Atanu Jana, Sangeun Cho, Supriya A. Patil, Abhishek Meena, Yongcheol Jo, Vijaya Gopalan Sree, Youngsin Park,Hyungsang Kim, Hyunsik Im* and Robert A. Taylor Materials Today, 55 , 110, 2022. DOI: https://doi.org/10.1016/j.mattod.2022.04.009
267. Decreased fast time-scale spectral diffusion of a non-polar InGaN quantum dot Claudius Kocher, John C. Jarman, Tongtong Zhu, Gunnar Kusch, Rachel A. Oliver, and Robert A. Taylor ACS Photonics, 9 , 275, 2022. DOI: https://doi.org/10.1021/acsphotonics.1c01613
266. Reconfigurable Low-Emissivity Optical Coating Using Ultrathin Phase Change Materials Nathan Youngblood, Clement Talagrand, Benjamin F. Porter, Carmelo Guido Galante, Steven Kneepkens, Graham Triggs, Syed Ghazi Sarwat, Dmitry Yarmolich, Ruy S. Bonilla, Peiman Hosseini, Robert A. Taylor, Harish Bhaskaran ACS Photonics, 9 , 90, 2022. DOI: https://doi.org/10.1021/acsphotonics.1c01128
265. Local Magnetic Field Promoted Photocatalytic Overall Water Splitting with Remarkable Solar-to-Hydrogen Efficiency Yiyang Li, Zihan Wang, Yiqi Wang, Andras Kovacs, Christopher Foo, Rafal Dunin-Borkowski, Y. H. Lu, Robert A. Taylor, Chen Wu and Edman Tsang Energy & Environmental Science, 15 , 265, 2022. DOI: https://doi.org/10.1039/D1EE02222A
264. Harvesting electrical energy using plasmon-enhanced light pressure in a platinum cut cone Ha Young Lee, Min Sub Kwak, Kyung-Won Lim, Hyung Soo Ahn, Geon-Tae Hwang, Dong Han Ha, Robert. A. Taylor, and Sam Nyung Yi Opt. Express 29 , 35161-35171, 2021. DOI: https://doi.org/10.1364/OE.438337
263. An insight study into the parameters altering the emission of a covalent triazine framework Panagiota Bika, Vitaly Osokin, Tatiana Giannakopoulou, Nadia Todorova, Mo Li, Andreas Kaidatzis, Robert Taylor, Christos Trapalis, Panagiotis Dallas Journal of Materials Chemistry, 9 , 13770, 2021. DOI: https://doi.org/10.1039/D1TC02985A
262. Quantification of Temperature-Dependent ChargeSeparation and Recombination Dynamics in Non-Fullerene Organic Photovoltaics Christopher C. S. Chan, Chao Ma, Xinhui Zou, Zengshan Xing, Guichuan Zhang,Hin-Lap Yip, Robert A. Taylor, Yan He, Kam Sing Wong, and Philip C. Y. Chow Advanced Functional Materials, 31 , 2107157, 2021. DOI: https://doi.org/10.1002/adfm.202107157
261. Resonantly pumped bright-triplet exciton lasing in caesium lead bromide perovskites Guanhua Ying, Tristan Farrow, Atanu Jana, Hanbo Shao, Hyunsik Im, Vitaly Osokin, Seung Bin Baek, Mutibah Alanazi, Sanjit Karmakar, Manas Mukherjee, Youngsin Park, Robert A. Taylor ACS Photonics, 8 , 2699, 2021. DOI: https://doi.org/10.1021/acsphotonics.1c00720
260. Exciton dynamics in monolayer graphene grown on a Cu(111) surface Youngsin Park, Guanhua Ying, Robert A. Taylor and Chan C. Hwang npj 2D Materials and Applications, 5 , 69, 2021. DOI: https://doi.org/10.1038/s41699-021-00252-x
259. Fe on molecular-layer MoS 2 as inorganic Fe-S 2 -Mo motifs for light-driven nitrogen fixation to ammonia at elevated temperatures Jianwei Zheng, Lilin Lu, Konstantin Lebedev, Simson Wu, Pu Zhao, Ian J. McPherson, Tai-Sing Wu, Ryuichi Kato, Yiyang Li, Ping-Luen Ho, Guangchao Li, Linlu Bai, Jianhui Sun, Dharmalingam Prabhakaran, Robert A. Taylor, Yun-Liang Soo, Kazu Suenaga, and Shik Chi Edman Tsang Chem Catalysis, 1 , 162, 2021. DOI: https://doi.org/10.1016/j.checat.2021.03.002
258. Imaging Nonradiative Point Defects Buried in Quantum Wells Using Cathodoluminescence Thomas F. K. Weatherley, Wei Liu, Vitaly Osokin, Duncan T. L. Alexander, Robert A. Taylor, Jean-François Carlin, Raphaël Butté, and Nicolas Grandjean Nano Letters, 21 , 5217, 2021. DOI: https://doi.org/10.1021/acs.nanolett.1c01295
257. Excitation and temperature dependence of the broad gain spectrum in GaAs/AlGaAs quantum rings Juyeong Jang, Seunghwan Lee, Minju Kim, Sunwoo Woo, Inhong Kim, Jihoon Kyhm, Jindong Song, Robert A. Taylor Applied Physics Letters, 117 , 212101, 2020.DOI: https://doi.org/10.1063/5.0020890
256. Two-photon Laser-written Photoalignment Layers for Patterning Liquid Crystalline Conjugated Polymer Orientation Yuping Shi, Patrick S. Salter, Mo Li, Robert A. Taylor, Steve J. Elston, Stephen M. Morris, and Donal D.C. Bradley Advanced Functional Materials, 2007493, 2020. DOi: https://doi.org/10.1002/adfm.202007493
255. Highly efficient photoluminescence and lasing from hydroxide coated fully inorganic perovskite micro/nano-rods G, Ying, V. Osokin, R. A. Taylor, A. Jana, T. Farrow and Y.S. Park Advanced Optical Materials, 2001235, 2020. DOI: https://doi.org/10.1002/adom.202001235
254. Coarse and fine-tuning of lasing transverse electromagnetic modes in coupled all-inorganic perovskite quantum dots Youngsin Park, Guanhua Ying, Atanu Jana, Vitaly Osokin, Claudius C. Kocher, Tristan Farrow, Robert A. Taylor and Kwang S. Kim Nano Research, 14 , 108, 2021. DOI: https://doi.org/10.1007/s12274-020-3051-y
253. Purcell enhancement of a deterministically coupled quantum dot in an SU-8 laser patterned photonic crystal heterostructure H. Shao, G. Ying, S. A. Lennon, F. S. F. Brossard, J. P. Griffiths, L. P. Nuttall, V. Osokin, E. Clarke, H. He, and R. A. Taylor Applied Physics Letters, 117 , 043103, 2020. DOI: https://doi.org/10.1063/5.0018673
252. Transmissivity and Reectivity of a TE-polarized Wave Incident on a Microcavity Containing Strongly Coupled Excitons with In-plane Uniaxially Oriented Transition Dipole Moments F. Le Roux, R. A. Taylor and D. D. C. Bradley physica stats solidi (a), 257 , 2000235, 2020. DOI: https://doi.org/10.1002/pssb.202000235
251. 2D Photocatalysts with Tuneable Supports for Enhanced Photocatalytic Water Splitting Yiyang Li, Simson Wu, Jianwei Zheng, Yung-Kang Peng, Dharmalingam Prabhakaran, Robert A. Taylor and Shik Chi Edman Tsang Materials Today, 41 , 34, 2020. DOI: https://doi.org/10.1016/j.mattod.2020.05.018
250. Optical Shaping of polarization anisotropy in a laterally-coupled-quantum-dot dimer Heedae Kim, Kwangseuk Kyhm, Robert A. Taylor, Jong Su Kim, Jin Dong Song, and Sungkyun Park Light Science and Applications, 9 , 100, 2020. DOI: https://doi.org/10.1038/s41377-020-0339-3
249. Faraday-cage-assisted etching of suspended gallium nitride nanostructures Geraint P Gough, Angela D Sobiesierski, Saleem Shabbir, Stuart Thomas, Daryl M Beggs, Robert A Taylor, Anthony J Bennett AIP Advances 10 , 055319, 2020. DOI: https://doi.org/10.1063/5.0007947
248. Non-Polar Nitride Single-Photon Sources Tong Wang, Rachel A. Oliver , Robert A. Taylor Journal of Optics, 22 , 073001, 2020. DOI: https://doi.org/10.1088/2040-8986/ab97c2
247. Enhanced photoluminescence quantum yield of MAPbBr3 nanocrystals by passivation using graphene Youngsin Park, Atanu Jana, Chang Woo Myung, Taeseung Yoon, Geungsik Lee, Claudius C. Kocher, Guanhua Ying, Vitaly Osokin, Robert A. Taylor, Kwang S. Kim Nano Research 3 , 932 2020. DOI: https://doi.org/10.1007/s12274-020-2718-8
246. Near-Strain-Free GaN/AlGaN Narrow Line Width UV Light Emission with Very Stable Wavelength on Excitation Power by Using Superlattices Mo Li, Feiliang Chen, Claudius Kocher, Hui Zhang, Shuxiao Li, Feng Huang, Jian Zhang, and Robert A. Taylor ACS Applied Electonic Materials, 2 , 571 2020. DOI: https://dx.doi.org/10.1021/acsaelm.9b00813
245. Enhanced and Polarization-Dependent Coupling for Photoaligned Liquid Crystalline Conjugated Polymer Microcavities F. Le Roux, R. A. Taylor, and D. D. C. Bradley, ACS Photonics, 7 , 3, 2020. DOI: https://doi.org/10.1021/acsphotonics.9b01596
244. Photocatalytic Water Splitting by N-TiO2 on MgO(111) with Exceptional Quantum Efficiencies at Elevated Temperature Yiyang Li, Yung-Kang Peng, Liangsheng Hu, Jianwei Zheng, Dharmalingam Prabhakaran, Simson Wu, Timothy J. Puchtler, Mo Li, Kwok-Yin Wong, Robert A. Taylor, and Shik Chi Tsang Nature Communications, 10 , 4421, 2019. DOI: https://doi.org/10.1038/s41467-019-12385-1
243. Unravelling the key role of surface features behind facet-dependent photocatalysis of anatase TiO2. Peng Y-K, Keeling B, Li Y, Zheng J, Chen T, Chou H-L, Puchtler TJ, Taylor RA, Tsang SCE Chemical Communications, 55 , 4415, 2019. DOI: https://doi.org/10.1039/C9CC01561B
242. III-V compounds as single photon emitters Wang Xu, Xu Lei, Jiang Yun, Yin Zhouyang, Chan Christopher C. S., Deng Chaoyong, and Taylor Robert A. Journal of Semiconductors, 40 , 071906, 2019.DOI: https://doi.org/10.1088/1674-4926/40/7/071906
241. Photonic molecules defined by SU-8 photoresist strips on a photonic crystal waveguide Stephen. A. Lennon, Frederic. S. F. Brossard, Luke P. Nuttall, Jiang Wu, Jonathan Griffiths, and Robert A. Taylor Optics Express, 26 , 32332, 2018. DOI: https://doi.org/10.1364/OE.26.032332
240. Mitigating the photocurrent persistence of single ZnO nanowires for low noise photodetection applications J-Ph. Girard, L. Giraudet, S. Kostcheev, B. Bercu, T.J. Puchtler, R.A. Taylor, and C. Couteau Nanotechnology, 29 505207, 2018.. DOI: https://doi.org/10.1088/1361-6528/aae417
239. Light controlled optical Aharonov-Bohm oscillations in a single quantum ring Heedae Kim, Seongho Parka, Rin Okuyama, Kwangseuk Kyhm, Mikio Eto, Robert A. Taylor, Gilles Nogues, Le Si Dang, Marek Potemski, Koochul Je, Jongsu Kim, Jihoon Kyhm, and Jindong Song Nano Letters, 18 , 6188-6194, 2018. DOI: http://dx.doi.org/10.1021/acs.nanolett.8b02131
238. Optical Aharonov-Bohm Oscillations with Disorder Effects and Wigner Molecules in a Single GaAs/AlGaAs Quantum Ring K. Kyhm, H.D. Kim, R. Okuyiama, M. Eto, K.C. Je, R.. Taylor, G.Nogues, L. S. Dang, A.A.L Nicholet, M. Potemski, J.S. Kim and J.D. Song V. M. Fomin (Ed.), Physics of Quantum Rings, Second Edition , Series: NanoSci. Technol. Springer International Publishing, Cham, 2018 ISBN 978-3-319-95158-4, ISBN 978-3-319-95159-1 (eBook), 586 p., 276 ill.
237. Room temperature InP/InGaAs nano-ridge lasers grown on silicon emitting at telecom-bands Yu Han, Wai Kit Ng, Chao Ma, Qiang Li, Si Zhu, Christopher C.S. Chan, Kar Wei Ng, Stephen Lennon, Robert A Taylor, Kam Sing Wong, and Kei May Lau Optica 5 , 918, 2018. DOI: https://doi.org/10.1364/OPTICA.5.000918
236. Linearly polarized photoluminescence of InGaN quantum disks embedded in GaN nanorods Youngsin Park, Christopher C. S. Chan, Luke Nuttal2, Tim J. Puchtler, Robert A. Taylor, Nammee Kim, Yongcheol Jo, and Hyunsik Im Scientific Reports 8 , 8124, 2018. DOI: http://dx.doi.org/10.1038/s41598-018-26642-8 .
235. Temperature induced crossing in the optical bandgap of mono and bilayer MoS2 on SiO2 Youngsin Park, Christopher C. S. Chan, Robert A. Taylor, Yongchul Kim, Nammee Kim, Yongcheol Jo, Seung W. Lee, Woochul Yang, Hyunsik Im, and Geunsik Lee Scientific Reports, 8 , 5380, 2018. DOI: http://dx.doi.org/10.1038/s41598-018-23788-3 .
234. Carrier confinement effects of InxGa1-xN/GaN multi quantum disks with GaN surface barriers grown in GaN nanorods Youngsin Park, Christopher C. S. Chan, Robert A. Taylor, Nammee Kim, Yongcheol Jo, Seung W. Lee, Woochul Yang, and Hyunsik Im Optical Materials, 78 , 365, 2018. DOI: https://doi.org/10.1016/j.optmat.2018.02.052 .
233. Highly polarized electrically driven single-photon emission from a non-polar InGaN quantum dot C. C. Kocher, T. J. Puchtler, J. C. Jarman, T. Zhu, T. Wang, L. Nuttall, R. A. Oliver and R. A. Taylor Applied Physics Letters 111 , 251108, 2017. DOI: https://doi.org/10.1063/1.5008720 .
232. CF2-bridged C60 dimers and their optical transitions Panagiotis Dallas, Shen Zhou, Stuart Cornes, Hiroyuki Niwa, Yusuke Nakanishi, Yasuhiro Kino, Tim Puchtler, Robert.A.Taylor, G.Andrew.D.Briggs, Hisanori Shinohara and KyriakosPorfyrakis ChemPhysChem, 18 , 3540, 2017. DOI: http://doi.org/10.1002/cphc.201701182 .
231. Deterministic optical polarisation in nitride quantum dots at thermoelectrically cooled temperatures Tong Wang, Tim J. Puchtler, Saroj K. Patra, Tongtong Zhu, John C. Jarman, Rachel A.Oliver, Stefan Schulz, and Robert A. Taylor Scientific Reports, 7 , 12067, 2017. DOI: http://dx.doi.org/10.1038/s41598-017-12233-6 .
230. Optical fabrication and characterisation of SU-8 disk photonic waveguide heterostructure cavities Luke P. Nuttall, Frederic S. F. Brossard, Stephen A. Lennon, Benjamin P. L. Reid, Jiang Wu, Jonathan Griffiths, and Robert A. Taylor Optics Express, 25 , 24615, 2017. Doi: https://doi.org/10.1364/OE.25.024615 .
229. Temperature-dependent fine structure splitting in InGaN quantum dots Tong Wang, Tim J. Puchtler, Tongtong Zhu, John C. Jarman, Claudius C. Kocher, Rachel A. Oliver, and Robert A. Taylor Applied Physics Letters, 111 , 053101, 2017. DOI: http://dx.doi.org/10.1063/1.4996861 .
228. A Nanophotonic Structure Containing Living Photosynthetic-Bacteria David M Coles, Lucas C. Flatten,Thomas Sydney, Emily Hounslow, Semion K Saikin, Alan Aspuru-Guzik, Vlatko Vedral, Joseph Kuo-Hsiang Tang, Robert A Taylor, Jason M Smith, and David G Lidzey Small, 13 , 1701777, 2017. DOI: https://doi.org/10.1002/smll.201701777 .
227. Polarisation-controlled single photon emission at high temperatures from InGaN quantum dots T. Wang, T. J. Puchtler T. Zhu, J. C. Jarman, L. P. Nuttall, R. A. Oliver and R. A. Taylor Nanoscale, 9 , 9421-9427, 2017. DOI: https://doi.org/10.1039/c7nr03391e .
226. Optical polarization in mono and bilayer MoS2 Youngsin Park, Nannan Li, Christopher C. S. Chan, Benjamin P. L. Reid, Robert A. Taylor, Hyunsik Im Current Applied Physics, 17 , 1153-1157, 2017. DOI: https://doi.org/10.1016/j.cap.2017.05.009 .
225. Organic molecule fluorescence as an experimental test-bed for quantum jumps in thermodynamics Cormac Browne, Tristan Farrow, Oscar C. O. Dahlsten1, Robert A. Taylo1, and Vlatko Vedral Proc. R. Soc. A 473 , 20170099, 2017. DOI: http://dx.doi.org/10.1098/rspa.2017.0099 .
224. Interplay between many body effects and Coulomb screening in optical bandgap of atomically thin MoS2 Youngsin Park, Sang Wook Hanb Christopher C. S. Chan, Benjamin P. L. Reid, Robert A. Taylor, Nammi Kim, Seung W. Lee, Yongcheol Joe, Hyunsik Im and Kwang S. Kim Nanoscale, 9 , 10647-10652, 2017. DOI: https://dx.doi.org/10.1039/C7NR01834G .
223. High-temperature performance of non-polar (11-20) InGaN quantum dots grown by a quasi-two-temperature method Tong Wang, Tim J. Puchtler, Tongtong Zhu, John C. Jarman, Rachel A. Oliver and Robert A. Taylor Physica Status Solidi B, 2017. DOI: http://dx.doi.org/10.1002/pssb.201600724 .
222. Theoretical and experimental analysis of radiative recombination lifetimes in nonpolar InGaN/GaN quantum dots Saroj Kanta Patra, Tong Wang, Tim J. Puchtler, Tongtong Zhu, Rachel A. Oliver, Robert A. Taylor, and Stefan Schulz Physica Status Solidi B, 2017. DOI: http://dx.doi.org/10.1002/pssb.201600675 .
221. Direct generation of linearly polarized single photons with a deterministic axis in quantum dots Tong Wang, Tim J. Puchtler, Saroj K. Patra, Tongtong Zhu, Muhammad Ali, Tom Badcock, Tao Ding, Rachel A. Oliver, Stefan Schulz, and Robert A. Taylor Nanophotonics, 6 , 1175, 2017. DOI: https://doi.org/10.1515/nanoph-2017-0027.
220. Two-dimensional Excitonic Photoluminescence in Graphene on a Cu Surface Youngsin Park, Yoo S. Kim, Chang Woo Myun, Robert A. Taylor, Christopher C. S. Chan, Benjamin P. L. Reid, Timothy J. Puchtler, Robin J. Nicholas, Tomba S. Laishram, Geunsik Lee, Chan C. Hwang, Chong Yun Park, Kwang S. Kim ACS Nano, 11 , 3207, 2017. DOI: http://dx.doi.org/10.1021/acsnano.7b00245 .
219. Long Stokes shifts and vibronic couplings in perfluorinated polyanilines Panagiotis Dallas, Ilija Rasovic, Tim Puchtler, Robert A.Taylor, and Kyriakos Porfyrakis ChemComm., 53 , 2602, 2017. DOI: http://dx.doi.org/10.1039/C7CC00471K
218. Electrically tunable organic-inorganic hybrid polaritons with monolayer WS2 L. C. Flatten, D. M. Coles, Z. He, D. G. Lidzey, R. A. Taylor, J. H. Warner, and J. M. Smith Nature Communications, 8 , Article number: 14097, 2017. DOI: http://dx.doi.org/10.1038/ncomms14097 .
217. Quasi-one-dimensional density of states in a single quantum ring Hee Dae Kim, Woojin Lee, Seongho Park, Kwangseuk Kyhm, Koochul Je, Robert A. Taylor, Gilles Nogues, Le Si Dang, and Jin Dong Song Scientific Reports, 7 , Article number: 40026, 2017. DOI: http://dx.doi.org/10.1038/srep40026
216. Ultrafast, Polarized, Single-Photon Emission from m-Plane InGaN Quantum Dots on GaN Nanowires Tim J. Puchtler, Tong Wang, Christopher X. Ren, Fengzai Tang, Rachel A. Oliver, Robert A. Taylor, and Tongtong Zhu Nano Letters, 16 , 7779, 2016, DOI: http://dx.doi.org/10.1021/acs.nanolett.6b03980
215. Exciton dipole-dipole interaction in a single coupled-quantum-dot structure via polarized excitation Heedae Kim, Inhong Kim, Kwangseuk Kyhm,Robert A. Taylor,Jong Su Kim, Jin Dong Song, Koo Chul Je and Le Si Dang Nano Letters, 16 , 7755, 2016, DOI: http://dx.doi.org/10.1021/acs.nanolett.6b03868
214. Quantum dot-like excitonic behavior in individual single walled-carbon nanotubes Xu Wang, Jack A. Alexander-Webber, Wei Jia, Benjamin P. L. Reid, Samuel D. Stranks, Mark J. Holmes, Christopher C. S. Chan, Chaoyong Deng, Robin J. Nicholas, and Robert A. Taylor Scientific Reports, 6 , Article number: 37167, 2016, DOI: http://dx.doi.org/10.1038/srep37167
213. Strong exciton-photon coupling with colloidal nanoplatelets in an open microcavity Lucas C. Flatten, Sotirios Christodoulou, Robin K Patel, Alexander Buccheri, David Martin Coles, Benjamin P. L. Reid, Robert Anthony Taylor, Iwan Moreels, and Jason M. Smith Nano Letters, 16 , 7137, 2016, DOI: http://dx.doi.org/10.1021/acs.nanolett.6b03433
212. Structure-Activity Correlations for Bronsted Acid, Lewis Acid and Photo- Catalysed Reactions of Exfoliated Crystalline Niobium Oxide Layers Edman Shik Chi Tsang, Yusuke Koito, Gregory J. Rees, John V. Hanna, Molly M.J. Li, Yung-Kang Peng, Tim Puchtler, Robert Taylor, Tong Wang, Hisayoshi Kobayashi, Ivo. F. Teixeira, M. Abdullah Khan, and Hannah Kreissl ChemCatChem 10.1002/cctc.201601131, 2016. DOI: http://dx.doi.org/10.1002/cctc.201601131
211. Room-temperature exciton-polaritons with two-dimensional WS2 Lucas Flatten, Zhengyu He, David Coles, Aurelien Trichet, Alex Powell, Robert A.Taylor, Jamie Warner, and Jason Smith Scientific Reports, 6 , Article number: 33134, 2016. DOI: http://dx.doi.org/10.1038/srep33134
210. Barrier engineering of a photonic molecule in a photonic crystal waveguide Frederic S. Brossard, Ben P. Reid, Luke Nutall, Stephen Lenon, Ray Murray, and Robert A. Taylor Conference on Lasers and Electro-Optics, OSA Technical Digest (2016) (Optical Society of America, 2016), paper SF1E.1. DOI:10.1364/CLEO_SI.2016.SF1E.
209. Carrier trapping and confinement in Ge nanocrystals surrounded by Ge3N4 Youngsin Park, Christopher C. S. Chan, Benjamin P. L. Reid, Luke Nuttall, Robert A. Taylor, Nam-Suk Lee, Young Mi Lee Scientific Reports 6 , Article number: 25449, 2016. DOI: http://dx.doi.org/10.1038/srep25449
208. Color depth modulation and resolution in Phase-Change Material nano-displays Carlos Rios, Peiman Hosseini, Robert A Taylor and Harish Bhaskaran Advanced Materials, 28 , 4720, 2016. DOI: http://dx.doi.org/10.1002/adma.201506238
207. Plasmonic Gas Sensing using Nanocube Patch Antennas Alexander W. Powell, David M. Coles, Robert A. Taylor, Andrew A.R. Watt, Hazel E. Assender and Jason M. Smith Advanced Optical Materials, 4 , 634, 2016. DOI: dx.doi.org/10.1002/adom.201500602
206. Charge separated states and singlet oxygen generation of Mono and Bis Adducts of C60 and C70 Panagiotis Dallas, Gregory Rogers, Ben Reid, Robert A.Taylor, Hisanori Shinohara, G.Andrew D.Briggs and Kyriakos Porfyrakis Chemical Physics, 465-466 , 28, 2016. DOI: http://dx.doi.org/10.1016/j.chemphys.2015.12.003 .
205. Observation of a biexciton Wigner molecule by fractional optical Aharonov-Bohm oscillations in a single quantum ring Hee Dae Kim, Rin Okuyamaa, Kwangseuk Kyhm, Mikio Eto, Robert A.Taylor, Aurelien L. Nicolet, Marek Potemski, Gilles Nogues, Le Si Dang, Koo-Chul Je, Jongsu Kim, Ji-Hoon Kyhm, Kyu Hyoek Yoen, Eun Hye Lee, Jun Young Kim, Il Ki Han, Wonjun Choi, and Jindong Song Nano Letters 16 , 27, 2016. DOI: 10.1021/acs.nanolett.5b02419
204. Towards witnessing quantum effects in complex molecules T. Farrow, R. A. Taylor and V. Vedral Faraday Discussions, 184 , 183, 2015. DOI: http://dx.doi.org/10.1039/C5FD00101C
203. Gain spectroscopy of Solution Based Semiconductor Nanocrystals in Tunable Optical Microcavities Robin K. Patel, Aurelien A. P. Trichet, David Coles, Philip R. Dolan, Simon Fairclough, Marina A. Leontiadou, Edman Tsang, David Binks, Eunjoo Jang, Hyosook Jang, Robert A. Taylor and Jason M. Smith Advanced Optical Materials, 4 , 187, 2016. DOI: http://dx.doi.org/10.1002/adom.201500363
202. Diffusion-Driven Continuous-Wave-Pumped Organic Dye Lasers David M. Coles, Aurelien A. P. Trichet, Philip P. Dolan, Robert A. Taylor, Claire Vallance and Jason M. Smith Laser & Photonics Reviews, 9 , 538, 2015. DOI: http://dx.doi.org/10.1002/lpor.201500090
201. Surface Effect Induced Optical Bandgap Shrinkage in GaN Nanotubes Young S. Park, Geunsik Lee, Mark J. Holmes, Christopher C. S. Chan, Benjamin P. L. Reid, Jack A. Alexander-Webber, Robin J. Nicholas, Robert A. Taylor, Kwang S. Kim, Sang W. Han, Y. Jo, J. Kim, Hyunsik Im, Woochel Yang Nano Letters, 15 , 4472, 2015. DOI: http://dx.doi.org/10.1021/acs.nanolett.5b00924
200. Non-polar InGaN quantum dot emission with crystal-axis oriented linear polarization B.P.L. Reid, C. Kocher, T. Zhu, F. Oehler, C.C.S. Chan, R.A. Oliver, and R.A. Taylor Applied Physics Letters, 106 , 171108, 2015. DOI: http://dx.doi.org/10.1063/1.4919656
199. Reduced Stark shift in three-dimensionally confined GaN/AlGaN asymmetric multi-quantum disks Y.S. Park, C.C.S. Chan, B.P.L. Reid, M.J. Holmes, D.M. Coles, J.A. Alexander-Webber, R.J. Nicjolas, R.A. Taylor, S-W. Lee, W. Yang and H. Im Optical Materials Express, 5 , 849, 2015. DOI: http://dx.doi.org/10.1364/OME.5.000849
198. The Influence of an Optical Well in Controlling the Mode Splitting in a Photonic Molecule Frederic S. F. Brossard, Robert A. Taylor, Ben P.L. Reid, David A. Williams, Peter D. Spencer, and Ray Murray Proceedings of the 16th International Conference on Transparent Optical Networks (ICTON), IEEE Xplore 2014.DOI: https://doi.org/10.1109/ICTON.2014.6876300
197. Growth of non-polar (11-20) InGaN quantum dots by metal organic vapour phase epitaxy using a two temperature method J. T. Griffiths, T. Zhu, F. Oehler, R. M. Emery, W. Y. Fu, B. P. L. Reid, R. A. Taylor, M. J. Kappers, C. J. Humphreys and R. A. Oliver APL Materials, 2 , 126101, 2014. DOI: dx.doi.org/10.1063/1.4904068
196. Strong coupling between chlorosomes of photosynthetic bacteria and a confined optical cavity mode David M Coles, Yanshen Yang, Yaya Wang, Richard T Grant, Robert A Taylor, Semion K Saikin, Alan Aspuru-Guzik, David G Lidzey, Joseph Kuo-Hsiang Tang and Jason M Smith Nature Communications, 5 , 5561, 2014. DOI: dx.doi.org/10.1038/ncomms6561
195. Hyperspectral imaging of exciton photoluminescence in individual carbon nanotubes controlled by high magnetic fields
J. Alexander-Webber, C. Faugeras, P. Kossacki, M. Potemski, X. Wang, H.D. Kim, S. Stranks, R.A. Taylor and R.J. Nicholas
Nano Letters 14 , 5194, 2014. DOI: dx.doi.org/10.1021/nl502016q .
194. Low gain threshold density of a single InGaP quantum well sandwiched by digital alloy B. Kim, K. Kyhm, K.C. Je, J.D. Song, S.Y. Kim, E.H. Le, R.A. Taylor Current Applied Physics 14 , 1293, 2014. DOI: dx.doi.org/10.1016/j.cap.2014.07.001
193. Temperature dependence of the radiative recombination time in ZnO nanorods under an external magnetic field of 6 T W. Lee, T. Kiba, A. Murayama, C. Sartel, V. Sallet, I. Kim, R. A. Taylor, Y. D. Jho, and K. Kyhm Optics Express 22 , 17959, 2014. DOI: dx.doi.org/10.1364/OE.22.017959
192. Observations of Rabi oscillations in a non-polar InGaN quantum dot Benjamin P. L. Reid, Claudius Kocher, Tongtong Zhu, Fabrice Oehler, Robert Emery, Christopher C. S. Chan, Rachel A. Oliver, and Robert A. Taylor Applied Physics Letters, 104 , 263108, 2014. DOI: dx.doi.org/10.1063/1.4886961
191. Non-polar (11-20) InGaN quantum dots with short exciton lifetimes grown by metal-organic vapour phase epitaxy Robert M. Emery, Tongtong Zhu, Fabrice Oehler, Benjamin Reid, Robert A. Taylor, Menno J. Kappers and Rachel A. Oliver Physica Status Solidi C 11 , 698, 2014. DOI: dx.doi.org/10.1002/pssc.201300525
190. High temperature stability in non-polar InGaN quantum dots: Exciton and biexciton dynamics B. P. L. Reid, T. Zhu, C. C. S. Chan, C. Kocher, F. Oehler, R. Emery, M. J. Kappers, R. A. Oliver and R. A. Taylor Physica Status Solidi C 11 , 702, 2014. DOI: dx.doi.org/10.1002/pssc.201300666
189. Growth of InGaN quantum dots with AlGaN barrier layers via modified droplet epitaxy R. A. Oliver, H. A. R. El-Ella, D. P. Collins, B. Reid, Y. Zhanga, F. Christie, M. J. Kappers, R. A. Taylor Materials Science and Engineering B 178 , 1390, 2013. DOI: dx.doi.org/10.1016/j.mseb.2013.08.011
188. Excited exciton and biexciton localised states in a single quantum ring H. D. Kim, K. Kyhm, R. A. Taylor, A. A. L. Nicolet, M. Potemski, G. Nogues, K. C. Je, E. H. Lee, and J. D. Song Applied Physics Letters 103 , 173106, 2013. DOI: dx.doi.org/10.1063/1.4826479
187. Photoluminescence mapping of coupled and detuned states in photonic molecules F.S.F. Brossard, B.P.L. Reid, C.C.S. Chan, X. L. Xu, J. P. Griffiths, D.A. Williams, R. Murray, and R.A. Taylor Optics Express, 21 , 16934, 2013. DOI: dx.doi.org/10.1364/OE.21.016934
186. Non-polar (11-20) InGaN quantum dots with short exciton lifetimes grown by metal-organic vapor phase epitaxy Tongtong Zhu, Fabrice Oehler, Benjamin Reid, Robert M. Emery, Robert A. Taylor, Menno J.Kappers, and Rachel A. Oliver Applied Physics Letters, 102 , 251905, 2013. DOI: dx.doi.org/10.1063/1.4812345
185. Optical studies of the surface effects from the luminescence of single GaN/InGaN nanorod LEDs fabricated on a wafer scale Christopher C. S. Chan, Benjamin P. L. Reid, Robert A. Taylor, YiDing Zhuang, Philip A. Shields, Duncan W. E. Allsopp and Wei Jia Applied Physics Letters, 102 , 111906, 2013. DOI: dx.doi.org/10.1063/1.479529
184. Origins of Spectral Diffusion in the Micro-Photoluminescence of Single InGaN Quantum Dots Benjamin P. L. Reid, Tongtong Zhu, Timothy J. Puchtler, Luke J. Fletcher, Christopher C. S. Chan, Rachel A. Oliver and Robert A. Taylor Japanese Journal of Applied Physics 52 , 08JE01, 2013. DOI: dx.doi.org/10.7567/JJAP.52.08JE01
183. Photoluminescence of Single GaN/InGaN Nanorod Light Emitting Diode Fabricated on a Wafer Scale Christopher C. S. Chan, Yi Ding Zhuang, Benjamin P. L. Reid, Wei Jia, Mark J. Holmes, Jack A. Alexander-Webber, Shingo Nakazawa, Philip A. Shields, Duncan W. E. Allsopp and Robert A. Taylor Japanese Journal of Applied Physics 52 , 08JE20, 2013. DOI: dx.doi.org/10.7567/JJAP.52.08JE20
182. Asymmetry of localised states in a single quantum ring: polarization dependence of excitons and biexcitons H. D. Kim, K. Kyhm, R. A. Taylor, G. Nogues, K. C. Je, E. H. Lee and J. D. Song Applied Physics Letters , 102 , 033112, 2013. DOI: dx.doi.org/10.1063/1.4789519
181. Optical cavity efficacy and lasing of focused ion beam milled GaN/InGaN micropillars Haitham A. R. El-Ella, Daniel P. Collins, Menno J. Kappers, Robert A. Taylor, and Rachel A. Oliver Journal of Applied Physics, 112 , 113516, 2012. DOI: dx.doi.org/10.1063/1.4768442
180. Investigation of Intense Luminescence from Chemically-Etched Silicon Nanowires M. Hadjipanayi, F. Voigt, V. Sivakov, X. Wang, R.A. Taylor, S. Christiansen, G.E. Georghiou Porceedings of the 27th European Photovoltaic Solar Energy Conference and Exhibition. DOI: dx.doi.org/10.4229/27thEUPVSEC2012-1BV.8.27
179. Design and fabrication of optical filters with very large stopband (~500 nm) and small passband (1 nm) in silicon-on-insulator Wei Jia, Jun Deng, Benjamin P.L. Reid, Xu Wang, Christopher C.S. Chan, Hong Wua, Xiangyin Li, Robert A. Taylor, Aaron J. Danner Photonics and Nanostructures Fundamentals and Applications, 10 , 447, 2012. DOI: dx.doi.org/10.1016/j.photonics.2012.02.001
178. Selective self-Assembly and Characterization of GaN Nanopyramids on m-Plane InGaN/GaN Quantum Disks Young S. Park, Mark J. Holmes, Robert A. Taylor, Kwang S. Kim, Seung-Woong Lee, HaeRi Ju and Hyunsik Im Nanotechnology, 23 , 405602, 2012. DOI: dx.doi.org/10.1088/0957-4484/23/40/405602
177. Amplified all-optical polarization phase modulator assisted by a local surface plasmon in Au-hybrid CdSe quantum dots Kwangseuk Kyhm, Koo-Chul Je and Robert A. Taylor Optics Express, 20 , 19735, 2012. DOI: dx.doi.org/10.1364/OE.20.019735
176. Growth and optical characterisation of multilayers of InGaN quantum dots Tongtong Zhu, Haitham A.R. El-Ella, Benjamin Reid, Mark J. Holmes, Robert A. Taylor, Menno J. Kappers, Rachel A. Oliver Journal of Crystal Growth, 338 , 262, 2012. DOI: 10.1016/j.jcrysgro.2011.11.001
175. Optical studies of GaN nanocolumns containing InGaN quantum disks and the effect of strain relaxation on the carrier distribution Mark J. Holmes, Young S. Park, Xu Wang, Christopher C. S. Chan, Benjamin P. L. Reid, HeeDae Kim, Jun Luo, Jamie H. Warner and Robert A. Taylor Physica Status Solidi C, 9 , 712, 2012 DOI: 10.1002/pssc.201100327
174. Optical Studies of Quantum Dot-like Emission from Localisation Centres in InGaN/GaN Nanorod Array LEDs Christopher C.S. Chan, Philip.A. Shields, Mark J. Holmes, YiDing Zhuang, Benjamin P.L. Reid, HeeDae Kim, Duncan W.E. Allsopp, and Robert A. Taylor Physica Status Solidi C, 9 , 635, 2012 DOI: 10.1002/pssc.201100386
173. Quantum confined carrier transition in a GaN/InGaN/GaN single quantum well bounded by AlGaN barriers Young S. Park, Mark J. Holmes, Robert A. Taylor, Seoung W. Lee, Seong-Ran Jeon, Im T. Yoon and Yoon Shon Solid State Communications. 151 , 1941, 2011. DOI: 10.1016/j.ssc.2011.09.017
172. Optical studies on a single GaN nanocolumn containing a single InxGa1-xN quantum disk M.J. Holmes, Y.S. Park, X. Wang, C. C. S. Chan, B. P. L. Reid, H.D. Kim, R. A. Taylor, J. H. Warner and J. Luo Applied Physics Letters, 98 , 251908, 2011. DOI: 10.1063/1.3601856
171. Non-equilibrium carrier dynamics and many body effects in highly excited GaN K. Kyhm, L. Rota and R. A. Taylor Phys. Status Solidi A, 208 , 1159, 2011. DOI: 10.1002/pssa.201000065
170. InGaN super-lattice growth for fabrication of quantum dot containing microdisks H.A.R. El-Ella, F. Rol, D.P. Collins, M.J. Kappers, R.A. Taylor, E.L. Hu and R.A. Oliver Journal of Crystal Growth, 321 , 113, 2011. DOI: 10.1016/j.jcrysgro.2011.02.012
169. Carrier dynamics of InxGa1-xN quantum disks embedded in GaN nanocolumns Mark J. Holmes, Young S. Park, Xu Wang, Christopher C. S. Chan, Anas F. Jarjour, Robert A. Taylor, Jamie H. Warner, Jun Luo, H. A. R. El-Ella, and R. A. Oliver Journal of Applied Physics, 109 , 063515, 2011. DOI: 10.1063/1.3558990
168. Strongly coupled single quantum dot in a photonic crystal waveguide cavity F. S. F. Brossard, X. L. Xu, D. A. Williams, M. Hadjipanayi, M. Hugues, M. Hopkinson, X. Wang and R.A. Taylor Proceedings of the 30th International Conference on the Physics of Semiconductors, AIP Conf. Proc. 1399 , 1017 (2011). DOI: 10.1063/1.3666724
167. Internal Field Shielding and the Quantum Confined Stark Effect in a Single InxGa1-xN Quantm Disk M.J. Holmes, Y.S. Park, J.H. Warner, J. Luo, X. Wang, A.F. Jarjour and R.A. Taylor Proceedings of the 30th International Conference on the Physics of Semiconductors, AIP Conf. Proc. 1399 , 545 (2011). DOI: 10.1063/1.3666495
166. Optical Studies on InxGa1-xN quantum disks Mark J. Holmes, Young. S. Park, Xu Wang, Christopher C. S. Chan, Anas F. Jarjour, Jun Luo, Jamie H. Warner, H. A. R. El-Ella R. A. Oliver and Robert A. Taylor Invited presentation at SPIE Photonics West, San Francisco, January 2011 Proc. of SPIE, 7937 , 793713, 2011. DOI: 10.1117/12.877149
165. Photoluminescence and Electroluminescence in InGaN/GaN Nano-Rod Array LEDs Fabricated on a Wafer Scale Philip A. Shields, Christopher Chan, Nathaniel Read, Duncan W. Allsopp, and Robert A. Taylor Proceedings of Solid-State and Organic Lighting 2010, Karlsruhe Germany, 21-24 June 2010, ISBN: 978-1-55752-899-5 DOI: 10.1364/SOLED.2010.SOThA3
164. Micro- and Time-resolved Photoluminescence in GaN Nanorods with Different Diameters Y.S. Park, H. Im, I.T. Yoon, S.K. Lee, Y.H. Cho, R.A. Taylor J. Korean Phys. Soc. 57 , 756-759, 2010. DOI: 10.3938/jkps.57.756
163. GaN nanorods grown on Si (111) substrates and exciton localization Young S. Park, Mark J. Holmes, Y. Shon, I. T. Yoon, Hyunsik Im, and Robert A. Taylor Nanoscale Research Letters, 6 , 81, 2011 DOI: 10.1186/1556-276X-6-81
162. High Up-Conversion Efficiency of YVO4:Yb,Er Nanoparticles in Water Down to the Single-Particle Level G. Dantelle, G. Mialon, S. Turckan, D.P. Collins, M. Hadjipanayi, R.A. Taylor, T. Gacoin, A. Alexandrou and J-P Boilot Journal of Physical Chemistry 114 22449-22454, 2010. DOI: 10.1021/jp107900z
161. Strongly coupled single quantum dot in a photonic crystal waveguide cavity F.S.F. Brossard, X. L. Xu, D.A. Williams, M. Hadjipanayi, M. Hugues, M. Hopkinson, X. Wang and R.A. Taylor Applied Physics Letters, 97 , 111101, 2010. DOI: 10.1063/1.3487937
160. Cavity modes of tapered ZnO nanowires Xiulai Xu, Frederic S. F. Brossard, David A. Williams, Daniel P. Collins, Mark J. Holmes, Robert A. Taylor and Xitian Zhang New Journal of Physics, 12 , 083052, 2010. DOI: 10.1088/1367-2630/12/8/083052
159. Quantum confined Stark effect of InGaN/GaN multi quantum disks grown on top of GaN nanorods Young S. Park, Mark J. Holmes,Tae W. Kang, and Robert A. Taylor Nanotechnology, 21 , 11540, 2010. DOI: 10.1088/0957-4484/21/11/115401
158. Q-factor measurements on planar nitride cavities Daniel P. Collins, Mark J. Holmes, Robert A. Taylor, Rachel A. Oliver, Menno J. Kappers and Colin J. Humphreys Physica Status Solidi C, 7 , 1866-1868, 2010. DOI: 10.1002/pssc.200983474
157. Optical properties of bulk-like GaN nanorods grown on Si (111) substrates by rf-plasma assisted molecular beam epitaxy Young S. Park, T. W. Kang, Hyunsik Im, Mark J. Holmes, and Robert A. Taylor Physica Status Solidi C, 7-8 , 2211-2213, 2010. DOI: 10.1002/pssc.200983428
156. Effects of surface recombination on exciton dynamics in GaN nanorods Y.S. Park, T. W. Kang, H. Im, S-K. Lee, Y-H. Cho, C. M. Park, M-S. Han, and R. A. Taylor Journal of Nanoelectronics and Optoelectronics, 4 , 307-311, 2009. DOI: https://doi.org/10.1166/jno.2009.1044
155. Cavity enhancement of single quantum dot emission in the blue R. A. Taylor, A F. Jarjour, D.P. Collins, M.J. Holmes, R.A. Oliver, M.J. Kappers and C.J. Humphreys Nanoscale Research Letters (2009). DOI: 10.1007/s11671-009-9514-4 http://www.springerlink.com/openurl.asp?genre=article&id=doi:10.1007/s11671-009-9514-4
154. Quantum confined Stark effect and corresponding lifetime reduction in a single InxGa1-xN quantum disk M.J. Holmes, Y.S. Park, J.H. Warner and R. A. Taylor Applied Physics Letters, 95, 181910, 2009. DOI: 10.1063/1.3257698
153. Acuminated fluorescence of Er3+ centres in endohedral fullerenes through the incarceration of a carbide cluster S.R. Plant , G. Dantelle, Y. Ito, T.C. Ng, A. Ardavan, H. Shinohara, R.A. Taylor, G.A.D. Briggs, K. Porfyrakis Chem. Phys. Lett. 476 , 41, 2009.
152. Mapping cavity modes of ZnO nanobelts X. Xu, F.S. Brossard, D.A. Williams, D.P. Collins, M.J. Holmes, R.A. Taylor and X. Zhang Applied Physics Letters, 94 , 231103, 2009.
151. Nitride-based quantum dots for single photon source applications A.F. Jarjour, R.A. Oliver, R.A. Taylor Review article in Physica Status Solidi (a), 2009. DOI 10.1002/pssa.200824455
150. Design of leaky modes of two-dimensional photonic crystal slabs to enhance the luminescence from Er3N@C80 fullerenes Y. Qi, A.F. Jarjour, X. Wang, R.A.Taylor and G. Zhang Optics Communications, 282 , 3637, 2009.
149. Optical properties of Er3+ in fullerenes and in β-PbF2 single-crystals G. Dantelle, A.Tiwari, R. Rahman, S.R. Plant, K. Porfyrakis, M. Mortier, R.A. Taylor, G.A.D. Briggs Optical Materials, 32 , 251, 2009.
148. Non-linear excitation and correlation studies of single InGaN quantum dots D.P. Collins, A.F. Jarjour, R.A. Taylor, M. Hadjipanayi, R.A. Oliver, M J. Kappers, C.J. Humphreys, and A. Tahraoui Phys. Stat. Sol. C, 6 , 864, 2009. 147. Two-photon excitation measurements on a single InGaN/GaN quantum dot D.P. Collins, A.F. Jarjour, M. Hadjipanayi, R.A. Taylor, R.A. Oliver, M.J. Kappers, C.J. Humphreys and A. Tahraoui Nanotechnology, 20 , 245702, 2009.
146. Experimental and theoretical study of the quantum-confined Stark effect in a single InGaN/GaN quantum dot under applied vertical electric field A.F. Jarjour, R.A. Oliver, A. Tahraoui , M.J. Kappers, R.A. Taylor, C.J. Humphreys 7th International Conference on Physics of Ligh-Matter Coupling in Nanostructures (PLMCN7). Superlattices and Microstructures 43 , 436, 2008.
145. Towards registered single quantum dot photonic devices K.H. Lee, F.S.F. Brossard, M. Hadjipanayi, X. Xu, F. Waldermann, A.M. Green, D.N. Sharp, A.J. Turberfield, D.A. Williams and R.A. Taylor Nanotechnology, 19 , 455307, 2008.
144. Electrically-driven single InGaN/GaN quantum dot emission A.F. Jarjour, R.A. Taylor, R.A. Oliver, M.J. Kappers, C.J. Humphreys and A. Tahraoui Applied Physics Letters 93 , 233103 2008.
143. Abnormal photoluminescence properties of GaN nanorods grown on Si (111) by molecular-beam epitaxy Y.S. Park, T.W. Kang and R.A. Taylor Nanotechnology, 19 , 475402, 2008.
142. The Growth of InAs Self-assembled Quantum Dots on GaAs Pyramidal Micro-mesas by Selective Area Molecular Beam Epitaxy J.C. Lin, R.A. Hogg, M.S. Skolnick, S. Zhang, H. Liu, and M. Hopkinson, M. Hadjipanayi and R.A. Taylor Submitted to Journal of Applied Physics, May 2008.
141. Fabrication of ultra thin single crystal diamond membranes B.A. Fairchild, P. Olivero, S. Rubanov, A.D. Greentree, F. Waldermann, R.A. Taylor, I. Walmsley, J. M. Smith, S. Huntington, B. Gibson, D.N. Jamieson, and S. Prawer Advanced Materials, 20 , 47934798, 2008. DOI: dx.doi.org/10.1002/adma.200801460
140. Properties of selective-area-growth GaN grown on various buffered Si(111) substrates by HVPE D. H. Shin, M. K. Bae, S. N. Yi, J. H. Na, K. H. Lee, R. A. Taylor, S. H. Doh and S. H. Park Journal of the Korean Physical Society, 51 , S220-S224, 2007.
139. Creating diamond color centers for quantum optical applications F. C. Waldermann, P. Olivero, J. Nunn, K. Surmacz, Z. Y.Wang, D. Jaksch, R. A. Taylor, I. A. Walmsley, M. Draganski, P. Reichart, A. D. Greentree, D. N. Jamieson, S. Prawer Diamond and Related Materials 16 , 1887, 2007.
138. Configuration-selective spectroscopic studies of Er3+ centers in ErSc2N@C80 and Er2ScN@C80 fullerenes A. Tiwari, G. Dantelle, K. Porfyrakis, R. A. Taylor, A. A.R. Watt, A. Ardavan, and G. A. D. Briggs Journal of Chemical Physics, 127 , 194504, 2007.
137. Magneto-optical studies of single-wall carbon nanotubes I. B. Mortimer,1 L.-J. Li, R.A. Taylor, G. L. J. A. Rikken, O. Portugall, and R. J. Nicholas Phys. Rev. B, 76 , 085404, 2007.
136. Comparison of exciton optical nonlinearities for resonant and non-resonant excitation K. Kyhm and R.A. Taylor Journal of the Korean Physical Society, 51 , 149-154, 2007.
135. Roughness Analysis of GaN Surfaces at Different Annealing Temperatures for an AlN Buffer Layer M. K. Bae, D. H. Shin, S. N. Yi, S.H. Doh, J. H. Na, K. H. Lee, R. A. Taylor and S.H. Park Journal of the Korean Physical Society, 51 , 209-213, 2007.
134. Growth and assessment of InGaN quantum dots in a microcavity: a blue single photon source R.A. Oliver, A.F. Jarjour, R.A. Taylor, A. Tahraoui, A. Zhang, M.J. Kappers and C.J. Humphreys Materials Science and Engineering B, 147, 108, 2008.
133. Cavity-enhanced blue single-photon emission from a single InGaN/GaN quantum dot A.F. Jarjour, R.A. Taylor, R.A. Oliver, M.J. Kappers, C.J. Humphreys and A. Tahraoui Applied Physics Letters, 91 , 052101, 2007.
132. Control of the oscillator strength of the exciton in a single InGaN/GaN quantum dot A.F. Jarjour, R.A. Oliver, A. Tahraoui, M.J. Kappers, C.J. Humphreys and R.A. Taylor Phys. Rev. Lett., 99 , 197403, 2007.
131. Photoluminescence Properties of a Single GaN Nanorod with GaN/AlGaN Multi-layer Quantum Discs S. N. Yi, J.H. Na, K.H. Lee, A. F. Jarjour, R.A. Taylor,Y.S. Park, T.W. Kang, S. Kim, D.H. Ha and G.A.D. Briggs Applied Physics Letters, 90 , 101901, 2007.
130. Crystal-encapsulation-induced band-structure change in single-walled carbon nanotubes: Photoluminescence and Raman spectra L-J Li, T-W Lin, J. Doig, I. B. Mortimer, J. G. Wiltshire, R. A. Taylor, J. Sloan, M. L. H. Green, and R. J. Nicholas Physical Review B, 74 , 245418, 2006.
129. Progress in the optical studies of single InGaN/GaN quantum dots A.F. Jarjour, R A. Oliver and R.A. Taylor Philosophical Magazine, 87 , 2077-2093, 2007.
128. PL, magneto-PL and PLE of the trimetallic nitride template fullerene Er3N@C80 M. A. G. Jones, J. J. L. Morton, K. Porfyrakis, G.A.D. Briggs, R.A. Taylor, A. Ardavan phys. stat. sol. (b), 243, 3037-3041, 2006.
127. Two-photon absorption from single InGaN/GaN quantum dots A.F. Jarjour, A.M. Green, T.J. Parker, R.A. Taylor, R.A. Oliver, G.A.D. Briggs, M.J. Kappers, C.J. Humphreys, R.W. Martin, I.M. Watson Physica E, 32 , 119-122, 2006. DOI: https://doi.org/10.1016/j.physe.2005.12.022
126. Dynamics of localized carriers in InGaN multi-quantum wells K. Kyhm and R.A. Taylor Journal of the Korean Physical Society, 49 , 538-541, 2006.
125. The dependence of carrier localization in InGaN/GaN multiple-quantum wells on well thickness J.H. Na, R.A. Taylor, K.H. Lee. A.M. Fox, T. Wang and P. Parbrook, S.N. Yi, Y.S. Park, J.W. Choi and J.S. Lee Applied Physics Letters, 89 , 253120, 2006.
124. Materials challenges for devices based on single, self-assembled InGaN quantum dots R.A. Oliver, A.F. Jarjour, A. Tahraoui , M. J. Kappers, R. A. Taylor, C.J. Humphreys Poster presentation at the International Conference on Nanoscience and Technology ICN&T, Basel 2006.
123. Enhanced single-photon emission from single quantum dots in two-dimensional photonic crystal cavities X. Xu, F. Brossard, D.A. Williams, R.A. Taylor, K.H. Lee and F. Waldermann Poster presentation at the Asian Conference on Quantum Information Science, September 1-4, 2006, Beijing, China.
122. Two-photon excitation spectroscopy of coupled asymmetric GaN/AlGaN quantum discs K.H. Lee, J.H. Na, R.A. Taylor, S.N. Yi, S. Birner, Y.S. Park, C.M. Park, T.W. Kang Nanotechnology, 17 , 5754-5758, 2006.
121. Time-resolved spectroscopy of non-thermal carrier dynamics in GaN K. Kyhm, R. Lota, R.A. Taylor, J.F. Ryan, N.J. Cain Current Applied Physics, 6 , 909-912, 2006.
120. Direct Optical Excitation of a Fullerene-Incarcerated Metal Ion M.A.G. Jones, R.A. Taylor, A. Ardavan, K.Porfyrakis and G.A.D. Briggs Chem. Phys. Lett., 428 , 303-306, 2006.
119. Accuracy of single quantum dot registration using cryogenic laser photolithography K.H. Lee, A.M. Green, F.S.F. Brossard, R.A. Taylor, D.N. Sharp, A.J. Turberfield, D.A. Williams and G.A.D. Briggs, Oral presentation at IEEE NANO 2006, Cincinnati, USA, July 2006.
118. Free Carrier Screening in Coupled Asymmetric GaN Quantum Discs K.H. Lee, J.H. Na, S. Birner, R.A. Taylor, S.N. Yi, Y.S. Park, C.M. Park and T.W. Kang Asia-Pacific Optical Communications (APOC) symposium, Proc. SPIE 6352 , U288-U296, 2006.
117. Two-Photon Excitation of Coupled Asymmetric GaN/AlGaN Quantum Discs K. H. Lee, J. H. Na, S. Birner, S. N. Yi, R. A. Taylor, Y. S. Park, C. M. Park, T. W. Kang AIP Conf. Proc. 893 , 981, 2007.
116. Characterization of tunnelling and free-carrier screening in coupled asymmetric GaN/AlGaN quantum discs K. H. Lee, J. H. Na, S. Birner, S. N. Yi, R. A. Taylor, Y. S. Park, C. M. Park, T. W. Kang AIP Conf. Proc. 893 , 1003, 2007.
115. Optical studies of nonlinear absorption in single InGaN/GaN quantum dots R. A. Taylor, A. F. Jarjour, R. W. Martin, I.M. Watson, R. A. Oliver, G. A. D. Briggs, M. J. Kappers and C. J. Humphreys AIP Conf. Proc. 893, 953, 2007.
114. Band structure changes in carbon nanotubes caused by MnTe crystal encapsulation L.J. Li, T.W. Lin, J. Doig, I. B. Mortimer, J. G. Wiltshire, R. A. Taylor, J. Sloan, M. L. H. Green and R. J. Nicholas AIP Conf. Proc. 893 , 1047, 2007.
113. The properties of selective area growth GaN grown on various buffered Si(111) substrates by HVPE D. H. Shin, H. J. Lee, M. K. Bae, M. H. Jung, S. N. Yi , J. H. Na, K. H. Lee, R. A. Taylor, S. H. Doh, Y. J. Cho and H. M. Cho Poster presentation ISBLLED 2006, Montpellier, France.
112. Enhancement of free-carrier screening due to tunneling in coupled asymmetric GaN/AlGaN quantum discs K.H. Lee, J.H. Na, R.A. Taylor, S.N. Yi, S. Birner, Y. S. Park, C. M. Park, and T. W. Kang Applied Physics Letters, 89 , 023103, 2006.
111. Study of Two-Photon Laser Photolithography with SU-8 at Cryogenic Temperatures K.H. Lee, A.M. Green, F.S.F. Brossard, R.A. Taylor, D.N. Sharp, A.J. Turberfield, D.A. Williams, G.A.D. Briggs Oral presentation at CLEO 2006.
110. The effects of nitrogen and boron doping on the optical emission and diameters of single-walled carbon nanotubes L.J. Li, M. Glerup, A. N. Khlobystov, J. G. Wiltshire, J.-L. Sauvajo, R. A. Taylor and R. J. Nicholas Carbon, 44 , 2752-2757, 2006.
109. The Structural Properties of GaN Grown on Si Substrates using various annealing conditions for the AlN Buffer Layers D.H.Shin, M.K.Bae, S.N.Yi, J.H.Na, A.M.Green, R.A.Taylor, Y.J.Cho, H.M.Cho, S.H.Park Journal of the Korean Physical Society, 48 , 1255-1258, 2006.
108. Surface investigation of a cubic AlN buffer layer and GaN grown on Si (111) and Si (100) as revealed by atomic force microscopy M.K.Bae, D.H.Shin, S.N.Yi, J.H.Na, A.M.Green, R.A.Taylor, Y.J.Cho, H.M.Cho, S.H.Park Journal of the Korean Physical Society, 49 , 1092-1096, 2006.
107. Carrier dynamics in InGaN/GaN multiple-quantum wells with narrow and wide well thicknesses J. H. Na, R. A. Taylor, A. M. Fox, T. Wang, P. Parbrook, A. Tahraoui, S. N. Yi, D. H. Shin and M. K. Bae Presented at the Korean Conference on Semiconductors, December, 2005
106.Cryogenic Two-Photon Laser Photolithography with SU-8 K.H. Lee, A.M. Green, F.S.F. Brossard, R.A. Taylor, D.N. Sharp, A.J. Turberfield, D.A. Williams, G.A.D. Briggs Applied Physics Letters, 88 , 143123, 2006.
105. Hot Carrier Dynamics and Carrier-Phonon Interaction in GaN K. Kyhm, R.A. Taylor and N.J. Cain Journal of the Korean Physical Society, 47 , S356-S359, 2005.
104. Time-resolved gain dynamics in InGaN MQW structures K. Kyhm, J.D. Smith and R.A. Taylor Journal of the Korean Physical Society, 47 , S360-S363, 2005.
103. Electron-Hole Plasma Mott Transition and Stimulated Emission in GaN K. Kyhm, J.D. Smith and R.A. Taylor Journal of the Korean Physical Society, 45 , S526-S529, 2004.
102. Registration single quantum dots using cryogenic laser photolithography K.H. Lee, A.M. Green, F.S.F. Brossard, R.A. Taylor, D.N. Sharp, J. Scrimgeour, O.M. Roche, J.H. Na, A.F. Jarjour, A.J. Turberfield, D.A. Williams, and G.A.D. Briggs Applied Physics Letters, 88 , 193106 , 2006.
101. Registration of Single Quantum Dots for Solid State Cavity Quantum Electrodynamics K.H. Lee, A.M. Green, F.S.F. Brossard, R.A. Taylor, A.J. Turberfield, D.A. Williams, and G.A.D. Briggs 18th IEEE LEOS Annual Meeting , Sydney, Australia, 113-114, 2005.
100. The recombination mechanism of Mg-doped GaN nanorods grown by plasma-assisted molecular beam epitaxy C.M. Park, Y.S. Park, T.W. Kang, J.H. Na, K.H. Lee and R.A. Taylor Nanotechnology, 17 , 913-916, 2006.
99. Two-photon absorption in single site-controlled InGaN/GaN quantum dots A.F. Jarjour, T. J. Parker, R.A. Taylor, R.W. Martin, K.H. Lee and I.M. Watson Phys. Stat. Sol. (c) 2 , 3843-3846, 2005.
98. Simulation of the Quantum-Confined Stark Effect in a Single InGaN Quantum Dot K.H. Lee, J. W. Robinson, J. H. Rice, J. H. Na, R. A. Taylor, R. A. Oliver, M. J. Kappers and C. J. Humphreys Oral presentation at The International Conference on Numerical Simulation of Optoelectronic Devices, NUSOD 2005.
97. Modelling the nonlinear photoluminescence intensity dependence observed in asymmetric GaN quantum discs with AlGaN barriers K. H. Lee, S. Birner, J. H. Na, R. A. Taylor, J. W. Robinson, J. H. Rice, Y. S. Park, C. M. Park and T. W. Kang Oral presentation at IEEE Nano 2005.
96. Two-photon absorption from InGaN/GaN quantum dots A.F. Jarjour, T .J. Parker, R. A. Taylor, R.W. Martin, I.M. Watson, R.A. Oliver, G.A.D. Briggs, M.J. Kappers and C.J. Humphreys Presented at MSS12, Albuquerque, July 2005.
95. Three methods for the growth of InGaN nanostructures by MOVPE R.A. Oliver, M.J. Kappers, N.K. van der Laak, C.J. Humphreys, G.A.D. Briggs, A. Jarjour, J.W. Robinson, R.A. Taylor, S. Yasin, D.G. Hasko, ICNS2005, April 2005.
94. Quantum-confined Stark effect in a single InGaN quantum dot under a lateral electric field J.W. Robinson, J.H. Rice, K.H. Lee, J.H. Na, R.A. Taylor, D.G. Hasko, R.A. Oliver, M.J. Kappers and C.J. Humphreys, G.A.D. Briggs Applied Physics Letters, 86 , 213104, 2005.
93. Two-Dimensional exciton behavior in GaN nanocolumns grown by molecular beam epitaxy J.H. Na, R. A. Taylor, J. H. Rice, J. W. Robinson, K. H. Lee, Y.S. Park, C.M. Park and T. W. Kang Applied Physics Letters, 86 , 123102, 2005.
92.Time-resolved and time-integrated photoluminescence studies of coupled asymmetric GaN quantum discs embedded in AlGaN barriers J.H. Na, R. A. Taylor, J. H. Rice, J. W. Robinson, K. H. Lee, Y.S. Park, C.M. Park and T. W. Kang Applied Physics Letters, 86, 083109, 2005.
91. Sub-wavelength Al mask apertures for addressing individual InGaN quantum dots S. Yasin, M.N. Khalid, J.H. Rice and R. A. Taylor Microelectronic Engineering 73-74 , 762-766, 2004.
90. Time-resolved gain saturation dynamics in InGaN multi-quantum well structures K. Kyhm, J. D. Smith, R. A. Taylor, J. F. Ryan, and Y. Arakawa Physica Status Solidi (c) 1 , 2508-2511, 2004.
89. Biexciton and exciton dynamics in single InGaN quantum dots J.H. Rice, J.W. Robinson, J.H. Na, K.H. Lee, R.A. Taylor, D.P. Williams, E.P. O'Reilly, A.D. Andreev, Y. Arakawa and S. Yasin Nanotechnology, 16 , 1477 - 1481, 2005.
88. Luminescence properties of isolated InGaN/GaN quantum dots R.W. Martin, P.R Edwards, R. A. Taylor, J. H. Rice, J. H. Na, J. W. Robinson, J. D. Smith, C. Liu and I. M. Watson Physica Status Solidi (a), 202 , 372-376, 2005.
87. Time-resolved dynamics in single InGaN quantum dots Invited presentation at "Ultrafast Phenomena in Semiconductors and Nanostructure Materials IX (OE04)", part of Photonics West 2005 R. A. Taylor, J. W. Robinson, J.H. Rice, K. H. Lee, A. Jarjour, J.H. Na, S. Yasin, R.A. Oliver, M.J. Kappers, C.J. Humphreys, G.A.D. Briggs, D.P. Williams, E.P. O'Reilly, A. D. Andreev and Y Arakawa Proc. of SPIE, 5725 , 297, 2005.
86. Quantum dot emission from site-controlled InGaN/GaN micropyramid arrays P.R. Edwards, R.W. Martin, I.M. Watson, C. Liu, R.A. Taylor, J.H. Rice, J.H. Na, J.W. Robinson and J.D. Smith Applied Physics Letters, 85 , 4281-4283, 2004.
85. Theoretical and experimental investigation of biexcitons and charged excitons in InGaN single quantum dots D.P. Williams, A.D. Andreev, E.P. O'Reilly, J.H. Rice, J.W. Robinson, A. Jarjour, J.D. Smith, R.A. Taylor, G.A.D. Briggs, Y. Arakawa Proceedings of ICPS-27 (AIP), Ed. Menendez and Van de Walle, 695-696, 2005.
84. Quantum dot emission from selectively-grown InGaN/GaN micropyramid arrays R.A. Taylor, J.H. Rice, J.H. Na, J.W. Robinson, P.R. Edwards, R.W. Martin, I.M. Watson, C. Liu Proceedings of ICPS-27 (AIP), Ed. Menendez and Van de Walle, 865-866, 2005.
83. Temporal variation in photoluminescence from single InGaN quantum dots J.H. Rice, J.W. Robinson, A. Jarjour, R.A. Taylor, R.A. Oliver, G.A.D. Briggs, M.J. Kappers, C.J. Humphreys Applied Physics Letters, 84 , 4110-4112, 2004.
82. Time-integrated and time-resolved photoluminescence studies of InGaN quantum dots J.W. Robinson, J.H. Rice, A. Jarjour, J.D. Smith, R.A. Taylor, R.A. Oliver, G.A.D. Briggs, M.J. Kappers, C.J. Humphreys, S. Yasin and Y. Arakawa Physica Status Solidi (c), 1 , 568-572, 2003.
81. Photoluminescence studies of exciton recombination and dephasing in single InGaN quantum dots J.H. Rice, J.W. Robinson, A. Jarjour, J.D. Smith, R.A. Taylor, R.A. Oliver, G.A.D. Briggs, M.J. Kappers, C.J. Humphreys IEEE Transactions on Nanotechnology, 3 , 343, 2004.
80. Time-resolved Dynamics in Single InGaN Quantum Dots J.W. Robinson, J.H. Rice, A. Jarjour, J.D. Smith, R.A. Taylor, R.A. Oliver, G. A.D. Briggs, M.J. Kappers, C.J. Humphreys and Y. Arakawa Applied Physics Letters, 83 , 2674 - 2676, 2003.
79. Nanoscale solid-state quantum computing A. Ardavan, M. Austwick, S. C. Benjamin, G. A. D. Briggs, T. J. S. Dennis, A. Ferguson, D. G. Hasko, M. Kanai, A. N. Khlobystov, B. W. Lovett, G. W. Morley, R. A. Oliver, D. G. Pettifor, K. Porfyrakis, J. H. Reina, J. H. Rice, J. D. Smith, R. A. Taylor, D. A. Williams, C. Adelmann, H. Mariett, R. J. Hamers Philosophical Transactions: Mathematical, Physical & Engineering Sciences, 361 , 1473 - 1485, 2003. 78. InGaN quantum dots grown by MOVPE via a droplet epitaxy route J. H. Rice, R. A. Oliver, J. W. Robinson, J. D. Smith, R. A. Taylor, M. Kappers, S. Yasin, C. J. Humphreys, and G. A. D. Briggs Physica E: Low-dimensional Systems and Nanostructures, 21 , 546-550, 2004
77. Dynamics of single InGaN quantum dots R. A. Taylor, J. W. Robinson, A. Jarjour, R. A. Oliver, J. H. Rice, J. D. Smith, M. Kappers, C.J. Humphreys, G. A. D. Briggs and Y. Arakawa Physica E: Low-dimensional Systems and Nanostructures, 21 , 285-289, 2004.
76. InGaN quantum dots grown by metal-organic vapour phase epitaxy employing a post-growth nitrogen anneal R.A. Oliver, G.A.D. Briggs, M.J. Kappers, C.J. Humphreys, S. Yasin, J.H. Rice, J.D. Smith, R.A. Taylor Applied Physics Letters, 83 , 755-757, 2003.
75. Growth of InGaN quantum dots on GaN by MOVPE, employing a growth temperature nitrogen anneal R.A. Oliver, M.J. Kappers, J.H. Rice, J.D. Smith, R.A. Taylor, C.J. Humphreys, G.A.D. Briggs Physica Status Solidi (c), 0 , 2515-2519, 2003.
74. Time-resolved Gain Dynamics in InGaN MQWs Using a Kerr Gate J.D. Smith, J.H. Rice, R.A. Taylor, J.F. Ryan, T. Someya and Y. Arakawa Physica E, 17 , 255-257, 2003.
73. Dynamics and Gain in Highly-excited InGaN MQWs R.A. Taylor, K. Kyhm, J.D. Smith, J.H. Rice, J.F. Ryan, T. Someya and Y. Arakawa Current Applied Physics, 2 , 321-326, 2002.
72. Time-resolved Gain Dynamics in InGaN MQWs Using a Kerr Gate J.D. Smith, J.H. Rice, R.A. Taylor, J.F. Ryan, T. Someya and Y. Arakawa Proceedings of The 26th Int. Conf. on the Physics of Semiconductors, Edinburgh, August 2002.
71. Comparison of Exciton-Biexciton with Bound Exciton-Biexciton Dynamics in GaN: Quantum Beats and Temperature Dependence of the Acoustic-Phonon Interaction K. Kyhm, T. Aoki, M. Gonokami, R.A. Taylor, J.F. Ryan, B. Beaumont and P. Gibart Phys. Rev. B, 65 , 193102, 2002.
70. Hot Phonons and Non-Thermal Carrier States in GaN K. Kyhm,R.A. Taylor, E.D. O'Sullivan, J.F. Ryan, N.J. Cain, V.Roberts and J.S. Roberts Physica B, 314 , 30-34, 2002.
69. Saturation of Gain in InGaN MQW Plasmas K. Kyhm, R.A. Taylor, J.F. Ryan, T. Someya and Y. Arakawa Physica B, 314 , 47-51, 2002.
68. Analysis of Gain Saturation in In0.02Ga0.98N/In0.16Ga0.84N Multiple Quantum Wells K. Kyhm, R.A. Taylor, J.F. Ryan, T. Someya and Y. Arakawa Applied Physics Letters, 79 , 3434-3436, 2001.
67. Quantum Beats of Free and Bound Excitons in GaN K. Kyhm, T. Aoki, M. Gonokami, R.A. Taylor, J.F. Ryan, B. Beaumont & P. Gibart Applied Physics Letters, 79 , 1097, 2001.
66. Biexciton-Exciton and Biexciton-Bound Exciton Dynamics in GaN: Quantum Beats and the Temperature Dependence of the Acoustic-Phonon Interaction K. Kyhm, R.A. Taylor, J.F. Ryan, T. Aoki, M. Gonokami, B. Beaumont & P. Gibart Physica Status Solidi (b), 228 , 475-479, 2001.
65. Strong Electron-LO Phonon Scattering and Hot Carrier Relaxation in GaN R.A. Taylor, K. Kyhm, S. Hess, E.D. O'Sullivan, J.F. Ryan, N.J. Cain, V.Roberts and J.S. Roberts Proceedings 25th Int. Conf. on the Physics of Semiconductors, Springer Proceedings in Physics, 87 , 1591, 2001.
64. Hot Carrier Relaxation in GaN: LO phonon Scattering and Excitonic Effects E.D. O'Sullivan, S. Hess, R.A. Taylor, N.J. Cain, V. Roberts, J.S. Roberts, J.F. Ryan Physica B, 272 , 402-405, 1999.
63. Femtosecond Exciton Dynamics and the Mott Transition in GaN Under Resonant Excitation S. Hess, R.A. Taylor, K. Kyhm, J.F. Ryan, B. Beaumont & P. Gibart Physica Status Solidi (b), 216 , 57-62, 1999.
62. Hot Carrier Relaxation by Extreme Electron - LO Phonon Scattering in GaN S. Hess, R.A. Taylor, E.D. O'Sullivan, J.F. Ryan, N.J. Cain, V. Roberts & J.S. Roberts Physica Status Solidi (b), 216 , 51-55, 1999
61. Stimulated Emission and Excitonic Bleaching in GaN Epilayers Under High-Density Excitation R.A. Taylor, S. Hess, K. Kyhm, J. Smith, J.F. Ryan, G.P. Yablonskii, E.V. Lutsebko, V.N. Pavlovskii & M. Heuken Physica Status Solidi (b), 216 , 465-470, 1999
60. Ultrafast secondary radiation of excitons in quantum wells: The transition from the coherent to the incoherent regime S. Haacke, G. R. Hayes, R. A. Taylor, M. Kauer, and B. Deveaud Radiative Processes and Dephasing in Semiconductors, D. Citrin, ed., Vol. 18 of OSA Trends in Optics and Photonics Series (Optical Society of America, 1998), paper RMD2 http://www.opticsinfobase.org/abstract.cfm?URI=RPDS-1998-RMD2
59. Femtosecond Dynamics of Resonantly Excited Excitons in GaN S. Hess, F. Walraet, R.A. Taylor, J.F. Ryan, B. Beaumont & P. Gibart Phys. Rev. B, 58 , 15973-15976, 1998
58. Time-resolved Bandgap Renormalization and Gain in GaN Epilayers S. Hess, R.A. Taylor, J.F. Ryan, B. Beaumont, P. Gibart, N.J. Cain, V. Roberts & J.S. Roberts Proc. Second International Symposium on Blue Laser and Light Emitting Diodes, Chiba, Japan, 673, 1998
57. Photoluminescence Studies of Mg-doped and Si-doped GaN Epilayers S. Hess, R.A. Taylor, J.F. Ryan, N.J. Cain, V. Roberts & J.S. Roberts Physica Status Solidi (b), 210 , 465-470, 1998
56. Optical Gain in GaN S. Hess, R.A. Taylor, J.F. Ryan, B. Beaumont & P. Gibart Applied Physics Letters, 73 , 199-201, 1998
55. Ultrafast dynamics of excitonic scattering and gain in narrow ZnCdSe/ZnSe multiple quantum wells S. Hess, R.A. Taylor, R.A. Adams, J.F. Ryan & R.M. Park J. of Crystal Growth, 185 , 645-649, 1998
54. Improving the signal-to-noise ratio of femtosecond luminescence upconversion by multichannel detection S. Haacke, R.A. Taylor, I. Bar-Joseph, M.J.S.P. Brasil, M. Hartig & B. Deveaud J. Opt. Soc. Am. B, 15 , 1410-1415, 1998
53. Dephasing of Excitons in Quantum Wells revealed by Femtosecond Rise of Secondary Radiation and by Degenerate Four-Wave-Mixing S. Haacke, G. Hayes, R.A. Taylor, J.L. Staehli & B. Deveaud 5th Int. Conf .on Optics of Excitons in Confined Systems, August 1997, Goettingen, Oral presentation
52. Relaxation Oscillations in the Gain Recovery of Gain-Clamped Semiconductor Optical Amplifiers: Simulation and Experiments J.L. Pleumeekers, T. Hessler, S. Haacke, M.-A. Dupertuis, P.E. Selbmann, R.A. Taylor, B. Deveaud, T. Ducellier, P. Doussiere, M. Bachmann & J.Y. Emery Topical Meeting on Optical Amplifiers and Their Applications, 21-23 July 1997, Victoria, Canada, Oral presentation
51. Femtosecond dynamics of secondary radiation formation from quantum well excitons R.A. Taylor, S. Haake, B. Deveaud, I. Bar Joseph & R. Zimmermann Physica E, 2 , 49-53, 1998
50. Efficient intersubband scattering via carrier-carrier interaction in quantum wells M. Hartig, S. Haake, P.E. Selbmann, B. Deveaud, R.A. Taylor & L. Rota Phys. Rev. Lett., 80 , 1940-1943, 1998
49. Efficient intersubband scattering via carrier-carrier interaction M. Hartig, S. Haake, P.E. Selbmann, B. Deveaud, R.A. Taylor & L. Rota Phys. Stat. Sol. (b), 204 , 159-161, 1997
48. Femtosecond Rayleigh scattering and luminescence in GaAs quantum wells under resonant excitation S. Haake, B. Deveaud & R.A. Taylor Oral presentation at CLEO/QELS 97, Baltimore
47. Relevance of Dephasing Processes for the Ultrafast Rise of Emission from Cold Excitons in Quantum Wells S. Haacke, G. Hayes, J.L. Staehli, B. Deveaud, R.A. Taylor & R. Zimmermann Phys. Stat. Sol. (b) 204 , 35-38, 1997
46. Direct observation in the temporal domain of relaxation oscillations in a semiconductor laser T. Hessler, S. Haake, J.L. Pleumeekers, P.E. Selbmann, M.A. Dupertuis, B. Deveaud, P. Doussiere, M. Bachmann, J.Y. Emery, T. Ducellier and R.A. Taylor Phys Stat. Sol. (b), 204 , 574-576, 1997
45. Time resolved relaxation oscillations in gain clamped semiconductor optical amplifiers by femtosecond pump and probe measurements T. Hessler, S. Haake, J.L. Pleumeekers, P.E. Selbmann, M.A. Dupertuis, B. Deveaud, R.A. Taylor, P. Doussiere, M. Bachmann, T. Ducellier & J.Y. Emery Quantum Semiclass. Opt., 9 , 675-679, 1997
44. Intersubband scattering rates in GaAs quantum wells under selective and resonant excitation, measured by femtosecond luminescence M. Hartig, S. Haake, R.A. Taylor, L. Rota & B. Deveaud Superlattices and Microstructures, 21 , 77-83, 1997
43. Resonant femtosecond emission from quantum well excitons: The role of Rayleigh scattering and luminescence S. Haacke, R.A. Taylor, R. Zimmermann, I. Bar-Joseph & B. Deveaud Phys. Rev. Lett., 78 , 2228, 1997
42. Intersubband scattering rates in GaAs quantum wells measured by femtosecond luminescence M. Hartig, S. Haake, R.A. Taylor, L. Rota & B. Deveaud Proc. 23rd Int. Conf. on the Physics of Semiconductors (ICPS-23), Berlin, Germany) (World Scientific Singapore), 753-756, 1996
41. Femtosecond emission from resonantly created quantum well excitons: the role of Rayleigh scattering S. Haake, B. Devaud, R.A. Taylor & I. Bar-Joseph Proc. 2nd International Conference on Excitonic Processes in Condensed Matter, 1996
40. Ultrafast optical absorption measurements of electron-phonon scattering in GaAs Quantum Wells K. Turner, L. Rota, R.A. Taylor & J.F. Ryan Proc. 9th Int. Conf. on Hot Carriers in Semiconductors, Ed. K. Hess, 23, Plenum Press, 1996
39. Ultrafast electric field induced nonlinear reponse in ZnSe/ZnSSe superlattices C.J. Stevens, M. Dabbicco, R.A. Taylor & J.F. Ryan J. of Crystal Growth., 159 , 835, 1996
38. Time-resolved study of stimulated emission in ZnSe/Zn(S,Se) superlattices M. Dabbicco, C.J. Stevens, R.A. Adams, R.A. Taylor, J.F. Ryan, R. Cingolani & I. Suemune J. of Crystal Growth., 159 , 657, 1996
37. Exciton recombination dynamics in ZnCdSe/ZnSe quantum wells R.A. Taylor, R.A. Adams, & R.M. Park J. of Crystal Growth., 159 , 822, 1996
36. Time-resolved exciton dynamics and stimulated emission from ZnCdSe/ZnSe multiple quantum well structures R.A. Taylor, R.A. Adams, J.F. Ryan & R.M. Park Solid State Electronics, 40 , 741, 1996
35. Exciton dynamics in ZnSe/ZnSxSe1-x superlattices M. Dabbicco, C.J. Stevens, R.A. Adams, R.A. Taylor, J.F. Ryan, R. Cingolani & I. Suemune Il Nuovo Cimento, 17 , 1429, 1995
34. Intersubband dynamics in GaAs quantum wells measured by femtosecond optical absorption spectroscopy K. Turner, L. Rota, R.A. Taylor & J.F. Ryan Applied Physics Letters, 66 , 3188, 1995
33. Picosecond photoluminescence intensity correlation measurements of hot carriers GaAs/AlGaAs quantum wells A.M. De Paula, J.F. Ryan, H.W.J. Eakin, M. Tatham, R.A. Taylor & A.J. Turberfield J. Luminescence, 59 , 303, 1994
32. Excitonic processes and lasing in ZnSSe/ZnSe superlattices C.J. Stevens, R. Cingolani, L. Calcagnile, M. Dabbicco, R.A. Taylor, J.F. Ryan, M. Lomascolo & I. Suemune Superlattices and Microstructures, 16 , 371, 1994
31. Time-resolved and CW optical studies of MBE-grown ZnTe/GaSb epilayers M.J. McNamee, R.A. Taylor, P.A. Snow, W. Hayes, D.E. Ashenford & B. Lunn Journal of Luminescence, 60 , 61 , 788, 1994
30. Ultrafast dynamics of photo-excited states in C60 T.N. Thomas, J.F. Ryan, R.A. Taylor, D. Mihailovic & R. Zamboni Europhysics Letters, 25 , 403, 1994
29. Time-resolved photoluminescence studies of stimulated emission and exciton dynamics in ZnSe/ZnS0.18Se0.82 superlattices C.J. Stevens, R.A. Taylor, J.F. Ryan, M. Dabbicco, M. Ferrara, R. Cingolani, Y. Kuroda & I. Suemune Solid State Electronics 37 , 1133, 1994
28. Time-resolved studies of hot carriers and excitons in MBE-grown ZnTe/GaSb epilayers M.J. McNamee, R.A. Taylor, P.A. Snow, W. Hayes, D.E. Ashenford & B. Lunn Semiconductor Science and Technology, 9 , 759, 1994
27. Exciton dynamics and recombination in ZnSe/ZnS0.18Se0.82 superlattices C.J. Stevens, R.A. Taylor, J.F. Ryan, R. Cingolani, M. Dabbicco, M. Ferrara & I. Suemune Semiconductor Science and Technology, 9 , 762, 1994
26. Femtosecond time-resolved optical studies of excited states in C60 T.N. Thomas, J.F. Ryan, R.A. Taylor, D. Mihailovic & R. Zamboni Electronic Properties of Fullerenes, Springer Series in Solid State Sciences 117 , 292, 1994 (Proceedings of the International Winter School on Electronic Properties of Novel Materials (IWEP), 1993)
25. Dynamic contributions to the optical Stark effect in semiconductors J.J. Baumberg, B. Huttner, R.A. Taylor & J.F. Ryan Phys. Rev. B, 48 , 4695, 1993
24. Time-resolved optical studies of photo-excited states in C60 T.N. Thomas, J.F. Ryan, R.A. Taylor, D. Mihailovic & R. Zamboni International Journal of Modern Physics B, 23 / 24 , 3931, 1993
23. Femtosecond hole-burning measurements in semiconductors R.A. Taylor, C.W.W. Bradley, N. Mayhew, T.N. Thomas & J.F. Ryan Journal of Luminescence, 53 , 321, 1992
22. Anisotropic optical Stark effect in GaSe J.J. Baumberg, R.A. Taylor & J.F. Ryan Proceedings of the 20th International Conference on the Physics of Semiconductors, (World Scientific), Ed. E.M. Anastassakis, J.D. Joannopoulos, 1891-1894, 1990
21. Femtosecond electron and hole thermalisation in AlGaAs C.W.W. Bradley, R.A. Taylor and J.F. Ryan Solid State Electronics, 32 , 1173, 1989
20. Investigation of inter-valley scattering and hot phonon dynamics in GaAs quantum wells using femtosecond luminescence intensity correlation A.M. De Paula, R.A. Taylor, C.W.W. Bradley, A.J. Turberfield and J.F. Ryan Superlattices and Microstructures, 6 , 199-202, 1989
19. The femtosecond optical Kerr effect in molten caesium-chloride C.W.W. Bradley, R.A. Taylor, J.F. Ryan and E.W.J. Mitchell Journal of Physics-Condensed Matter, 1 , 2715-2719, 1989
18. Femtosecond carrier thermalisation in AlGaAs C.W.W. Bradley, R.A. Taylor, J.F. Ryan Proc. 19th Int. Conf. on the Physics of Semiconductors, (Polish Acad. of Sci.), Ed. W. Zawadski, 1353, 1988
17. Energy relaxation in p-GaAs and n-GaAs quantum wells - confinement effects M. Tatham, R.A.Taylor, J.F. Ryan, W.I. Wang and C.T. Foxon Solid-state Electronics, 31 , 459-462, 1988
16. Time-resolved exciton photoluminescence in GaSe and GaTe R.A. Taylor and J.F. Ryan Journal of Physics C - Solid State Physics, 20 , 6175-6187, 1987
15. Time-resolved photoluminescence study of the formation and dissociation of excitonic molecules in GaSe R.A. Taylor, S.E. Broomfield, J.F. Ryan and F. Levy Proc. 18th Int. Conf. on the Physics of Semiconductors, (World Scientific), Ed. O. Engstrom, 1811-1814, 1987
14. Time-resolved hot luminescence from p-type GaAs-GaAlAs quantum wells J.A.P. Da Costa, R.A. Taylor, A.J. Turberfield, J.F. Ryan and W. Wang Proc. 18th Int. Conf. on the Physics of Semiconductors, (World Scientific), Ed. O. Engstrom, 1327-1330, 1987
13. Time-resolved photoluminescence from hot two-dimensional carriers in GaAs - GaAlAs MQWs J.F. Ryan, R.A. Taylor, A.J. Turberfield and J.M Worlock Surface Science, 170 , 511-519, 1986
12.. Picosecond photoluminescence measurements of Landau-level lifetimes and time-dependent Landau-level line broadening in modulation-doped GaAs-GaAlAs multiple quantum wells R.A. Taylor, A.J. Turberfield and J.M Worlock Physica b, 134 , 318-322, 1985
11. Picosecond studies of luminescence in polythiophene and polydiacetylene K.S. Wong, W. Hayes, T. Hattori, R.A. Taylor, J.F. Ryan, K. Kaneto, Y. Yoshino and D. Bloor Journal of Physics C - Solid State Physics, 18 , L843-847, 1985
10. Stimulated recombination and the dynamic Mott transition in GaTe C.N. ironside, R.A. Taylor and J.F. Ryan Proc. 17th Int. Conf. on the Physics of Semiconductors, (Springer), Ed. J.D. Chadi and W.A. Harrison, 1371, 1985
9. Hot electron relaxation and trapping in modulation-doped GaAs-AlGaAs multiple quantum well heterostructures J.F. Ryan, R.A. Taylor, A.J. Turberfield, A. Maciel, J.M. Worlock, A.C.Gossard and W. Wiegmann Proc. 17th Int. Conf. on the Physics of Semiconductors, (Springer), Ed. J.D. Chadi and W.A. Harrison, 567, 1985
8. Time-resolved photoluminescence of two-dimensional hot carriers in GaAs-AlGaAs heterostructures J.F. Ryan, R.A. Taylor, A.J. Turberfield, A. Maciel, J.M. Worlock, A.C.Gossard and W. Wiegmann Physical Review Letters, 53 , 1841-1844, 1984
7. Photothermal detection of picosecond photoinduced dichroism C.N. Ironside, R.A. Taylor and J.F. Ryan Journal de Physique, 44 , 579 -585, 1983
6. High-resolution spectroscopy using picosecond pulse trains A.I. Ferguson and R.A. Taylor Proceedings of the SPIE, 369 , 366-373, 1983
5. Picosecond continuum generation and spectroscopy A.I. Ferguson and R.A. Taylor Proceedings of the SPIE, 369 , 379-384, 1983
4. Picosecond time-resolved luminescence of GaTe C.N. Ironside, J.F. Ryan and R.A. Taylor Journal of the Optical Society of America, 73 , 1386, 1983
3. Picosecond studies of luminescence of cis polyacetylene W. Hayes, C.N. Ironside, J.F.Ryan, R.P. Steele, R.A.Taylor, Journal of Physics C - Solid State Physics, 16 , 1729-1732, 1983
2. Active mode stabilization of synchronously pumped dye lasers A.I. Ferguson and R.A. Taylor Picosecond Phenomena III, Springer, 31, 1982
1. Active-mode stabilization of a synchronously pumped mode-locked dye-laser A.I. Ferguson and R.A. Taylor Optics Communications, 41 , 271-276, 1982
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- Learn Top Effective Tips For Paper Presentation In Board Exams
The Power of Paper Presentation in Board Exams
Let’s know about the useful paper presentation tips to be followed in board exams.
"Paper presentations are not just about conveying information; they are about crafting narratives that captivate, educate, and inspire."
The presentation of an answer sheet is quite crucial in the context of exams. While the content and quality of your answers are critical, how you present them can significantly impact the examiner's assessment of your work. How you organise and structure your answers on paper is referred to as an answer sheet presentation, and it includes characteristics such as handwriting, formatting, headings, and overall neatness.
Also Read: 7 Effective Ways to Understand Difficult Concepts
This article explores the significance of paper presentation in board exams , focusing on readability, structure and organisation, clarity of expression, time management, professionalism, and attention to detail. Understanding the value of correctly presenting your answers can increase your chances of effectively transmitting your knowledge and skills, thus increasing your exam result.
How to Present a Paper in Exam Neatly
Paying attention to many areas of presenting a paper neatly in an exam entail paying attention to numerous aspects of its presentation. Here are some tips to help you learn how to present a paper in exam neatly :
1. Follow the Instructions Specified : Before answering the questions, carefully read the directions provided by the exam invigilator or mentioned on the exam paper. Follow any formatting, margin, or additional sheet rules provided.
2. Use Readable Handwriting : Use clear and legible handwriting for board exams to write your answers. If the examiner does not understand your writing, it may result in misunderstandings or grading errors. Use a comfortable writing speed and take your time to ensure that your words are legible.
3. Begin with a Clear and Informative Heading : Begin each answer with a clear and informative heading. Include the question number or title, and use highlighting or bold type to separate it from the rest of the content. This allows the examiner to more easily recognise and follow your answers.
4. Maintain Proper Formatting : If there are any formatting requirements, such as bullet points, numbering, or indentation, make sure to follow them. Consistency in formatting makes a visually pleasing answer sheet and aids in organising your thoughts.
5. Allow Enough Space : Allow enough space for each answer, with enough for additional additions or adjustments. Refrain from cramming your writing into a limited space because it will make your answers challenging to understand and may need clarification. If you run out of space, clearly indicate where you have continued your answer on an additional sheet.
6. Use Subheadings or Paragraphs : Use paragraphs to distinguish and divide your answers if a question has many parts or sub-questions. This makes it easy for the examiner to recognise and analyse each component of your answer separately.
7. Highlight Crucial Points : Use underlining or highlighter to emphasise essential points or keywords. This draws attention to important information and makes your answers stand out.
8. Review and Edit :
Before submitting your paper, review and edit your replies.
Check for spelling and grammatical mistakes, and make sure your sentences are clear and concise.
In your presentation, correct any errors or inconsistencies.
Paper Presentation Tips
Answer Questions in Order : Unless otherwise specified, it is best to answer questions in the order they appear in the paper. This keeps the logical flow going and avoids misunderstandings between you and the examiner.
Begin with a Concise and Clear Introduction : For essay-style questions or more extended answers, start with a brief introduction highlighting your key points or thesis. This allows the examiner to comprehend the direction of your answer right away.
Use Bullet Points or Numbered Lists : Consider utilising bullet points or numbered lists when presenting lists or multiple points. This improves readability and makes recognising and evaluating each effectiveness easier for the examiner.
Use Diagrams or Pictures : Include diagrams, flowcharts, or pictures to support your answers. Visual representations can more effectively convey information and make your answers more engaging.
Correctly Cross Out Errors : Instead of scribbling it out, neatly cross it with a single line if you make a mistake while writing. This shows that you know the inaccuracy and helps keep your answer sheet tidy.
Conclusion:
P aper presentation in board exams is critical for effectively communicating your knowledge and skills to the examiner. You can improve the presentation of your answer sheet by the suggestions provided in the article.
Remember that correct paper presentation in board exams improves readability and demonstrates professionalism and attention to detail. Presenting your answers effectively can make a favourable impression on the examiner and increase the overall impact of your exam result.
"In the realm of board exams, a powerful paper presentation can be the key that unlocks success."
FAQs on The Power of Paper Presentation in Board Exams
1. How can I improve the quality of handwriting for board exams?
Work on writing slowly and legibly. Take time to form each letter and carefully keep the regular spacing between words. Consider utilising ruled or grid paper to guide your writing if necessary.
2. What should I do if I make an error when composing my answers?
If you make a mistake, cross it out neatly with a single line. Scribbling or smearing the text is not permitted. This shows the examiner that you know the problem and allows them to read your corrected answer.
3. Do I have to draw diagrams or illustrations for exams?
Diagrams or illustrations help clarify your explanations or support your answers. However, include them only when they are relevant and add value to your comments. If you draw diagrams, make sure they're legible, labelled, and appropriately depict the information you're trying to convey.
4. Do I need to use a ruler to underline headings?
While employing a ruler can aid in creating straight lines, it is only sometimes necessary. You can do it freehand if your underlining is excellent and consistent. However, a ruler might be a helpful tool if you have trouble keeping straight lines.
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1st Year Physics Paper Presentation :
We know you want 1st Year Physics Paper Presentation PDF Download Punjab Board . That is why we uploaded the Class 11 notes. These notes benefit students with little time to write comprehensive notes for themselves.
Qais writes these notes, the topper of KIPS College Faisalabad. HE got 1059 marks in FSC and had a 2nd position in FAISALABAD BOARD . He also got 181 marks in the MDCAT . Now, he is a student at King Edward Medical University Lahore.
We provide you with his. The notes from the 1st Year Physics Paper Presentation are very comprehensive. So by following these notes, you will surely get benefits.
BENEFITS of 1st Year Physics Paper Presentation:
- Time-Saving: Save valuable study time with our well-organized and targeted notes, allowing you to focus on mastering the material rather than sifting through extensive textbooks.
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- Scoring Edge: Gain a competitive edge with insights from top-performing students. Our notes are designed to help you not just pass but excel in your physics exams.
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In conclusion, our “1st Year Physics Paper Presentation ” provides a holistic and effective approach to mastering physics for 11th-class students. Elevate your learning experience and boost your exam performance with our top-quality notes crafted for success.
KEY FEATURES of Physics Presentation Notes:
- Comprehensive Coverage: Our 1st year notes cover the entire syllabus for the 11th class, ensuring that no topic is left unexplored. From fundamental principles to advanced concepts, we’ve got it all covered.
- To-the-Point Explanations: We understand the importance of clarity in learning complex subjects. That’s why our notes provide concise and clear explanations, making it easier for students to grasp even the most challenging concepts.
- Illustrative Diagrams and Examples: Visual aids can significantly enhance understanding of the syllabus.
- Topper Insights: Crafted with inputs from top-performing students, our notes incorporate insights and strategies that have proven successful in scoring high marks. Learn from the best and elevate your performance.
- Exam-Oriented Approach: .We focus on key topics and frequently asked questions to help students prepare effectively and efficiently.
IMAGES
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The Physics of the Egyptian Pyramids. Nanowires. Magnus effect and its applications. Sustainable energy ( PPT 2) The Physics of Fire ( PPT) The Motion of the Planets. Artificial Intelligence (AI) in Our Everyday Life. The String theory: A theory of Everything. Electromagnetism and Its applications in daily life.
How to design and deliver effective scientific presentations? This pdf file from the University of Illinois provides practical tips and examples for physics students who are preparing for oral exams or thesis defense. Learn how to adjust your presentation to your audience, identify the main points, and use visual aids.
Brad R. Conrad, PhD, Director of SPS and Sigma Pi Sigma. Crafting an effective presentation has significant implications on how we best communicate science and can help propel a career to new heights. It is important to understand the keys to effectively presenting and communicating your work. Frank McKay, AZC Zone 17 and SPS Member, University ...
Preparation of a scientific presentation involves three separate stages: outlining the scientific narrative, preparing slides, and practicing your delivery. Making the slides of your talk without first planning what you are going to say is inefficient. Here, we provide a 4 step guide to writing your scientific presentation:
Top 101 Physics Topics For Presentation. Quantum Biology: Biological Processes from a Quantum Perspective. Quantum Astrophysics: Applying Quantum Mechanics to Cosmological Phenomena. Quantum Gravity: Unifying Quantum Mechanics and General Relativity. Quantum Cosmology: Cosmological Models Based on Quantum Theory.
Download the Energy and Conservation Laws - Physics - 10th Grade presentation for PowerPoint or Google Slides. High school students are approaching adulthood, and therefore, this template's design reflects the mature nature of their education. Customize the well-defined sections, integrate multimedia and interactive elements and allow space ...
Paper presented at the Physics Education Research Conference 2019, Provo, UT, July 24-25, 2019. B. Gutmann "Tools for underprepared students in engineering physics with a focus on online mastery learning exercises". Presentations made by the Illinois PER group at the 2019 American Association of Physics Teachers Summer Meeting and Physics ...
Paper Presentation. Below is a list of seminal papers in nuclear and particle physics. You are asked to form a team of two and pick a paper (first come first served). Please review the paper and prepare a 20-minute presentation summarizing the paper and also setting it into context. You can also suggest a paper not listed below.
Publish or Perish - Presentation of Scientific Results Intermediate Laboratory - Physics 2151W is focused on significantly improving the students' writing skills with respect to producing scientific papers, to do peer reviews, and presentations at the Physics Department Mini-Workshop. Third Edition, 2013
Mastering the Art of Oral Presentations by Don Fulop; John P. Stewart. ISBN: 9781119550105. Publication Date: 2019-03-27. Mastering the Art of Oral Presentations is your expert guide to delivering memorable and effective speeches and presentations. Projecting Enthusiasm: the Key to Dynamic Presentations for Professionals by Robert T. Tauber.
Publications and Conference Presentations. 284. Electrolyte-assisted polarization leading to enhanced charge separation and solar-to-hydrogen conversion efficiency of seawater splitting. Yiyang Li, Hui Zhou, Songhua Cai, Dharmalingam Prabhakaran, Wentian Niu, Alexander Large, Georg Held, Robert A. Taylor, Xin-Ping Wu, and Shik Chi Edman Tsang.
J. F. Presentation of Scientific Results Hint 1 Pick a published paper you like and try to emulate its structure and style Learn from eminent physics writers Some of my favorite physics writings are: •S. Weinberg: Relativity and Cosmology •Feynman, Leighton, Sands: Feynman Lectures in Physics •Landau and Lifschitz: Course in Theoretical ...
Paper Presentation of Physics | Paper attempt skillsIn this video,I will tell you about paper presentation in board exams.Paper Presentation is very importan...
Derivations Booklet: https://drive.google.com/file/d/1VSLvOTbtRSrH3xiXSJxIfGrkZ_GKfYnC/view?usp=share_link Chapter-Wise Previous Year Questions: https://dri...
SPS recommends using PowerPoint to design and lay out your poster, but there are other options. Before you start designing, check the poster dimensions specified by the conference and scale the poster accordingly. It is typical to do a 42-inch by 42-inch poster. The top section of the poster is your identifier.
Physics Paper: https://www.instagram.com/p/CPkxur4HZGV/?utm_medium=copy_linkDear Students, You can also watch other videos related to E-Sheets in complete de...
Physics related research discussions | Explore the latest full-text research PDFs, articles, conference papers, preprints and more on PHYSICS. Find methods information, sources, references or ...
In conclusion, our "1st Year Paper Presentations " provides a holistic and effective approach to mastering physics for 11th-class students. Elevate your learning experience and boost your exam performance with our top-quality notes crafted for success.
1. Follow the Instructions Specified: Before answering the questions, carefully read the directions provided by the exam invigilator or mentioned on the exam paper. Follow any formatting, margin, or additional sheet rules provided. 2. Use Readable Handwriting: Use clear and legible handwriting for board exams to write your answers.
Final exams on the horizon? Kick-start your revision with our 4-day online A Level Physics Easter revision courses for AQA, Edexcel and OCR (A). Check them out now! For each of the exam boards below, there are revision notes, factsheets, questions from past exam papers separated by topic and videos.
BENEFITS of 1st Year Physics Paper Presentation: Time-Saving: Save valuable study time with our well-organized and targeted notes, allowing you to focus on mastering the material rather than sifting through extensive textbooks. Improved Retention: The combination of clear explanations, illustrative examples, and topper insights enhances your ability to retain and recall information during exams.
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Copy to the respective Heads of Directorates, Organizations and Institutions as indicated below with a request to disseminate the information to all the schools undertheir jurisdiction:
In this video i am going to show you paper presentation of all subject including physics chemistry biology islamyat and pak studies. You will learn paper pre...