Imperial physicists have recreated the famous double-slit experiment, showing light behaving as both a wave and particle, but in time instead of space. By firing light through a material that changes its properties in femtoseconds, the experiment reveals more about the fundamental nature of light, creating a stepping-stone to creating the ultimate materials that can minutely control light in both space and time. The experiment has implications for new technologies and analogs for studying fundamental physics phenomena like black holes.

Have you ever wondered how touchscreens work? The answer is more fascinating than you might think. Touchscreens use capacitance or resistance to detect touch, but how does this work exactly? Conductive materials allow electrons to flow around atoms, forming an electric current that is used to complete the circuit. Capacitive touchscreens are generally easier to use because they interact directly with your finger, while resistive touchscreens require force to detect touch. When you touch a screen, your finger acts like a third electrical line, interacting with the existing electric field, which induces a weak electric current that travels through your finger and back into the phone. Understanding how touchscreens work is not only intellectually interesting, but it also has practical applications. Knowing how to troubleshoot touchscreen issues or how certain objects can activate the screen can come in handy. So next time you use your phone, think about the technology behind it and the wonders of conductivity and capacitance.

Unlock the future of electronics with 2D materials! MIT engineers have developed a revolutionary method to fabricate tiny transistors from 2D materials like transition-metal dichalcogenides (TMDs) that conduct electricity better than silicon. The method allows chip manufacturers to grow these materials on existing silicon wafers, preserving their perfect crystalline form. Get ready to catch up to Moore's Law with next-generation electronic devices!

Welcome, high school students! Today, we're diving into the fascinating world of Smith-Purcell radiation, a phenomenon that occurs when charged particles move near a periodic surface, producing electromagnetic waves. This topic is a captivating example of the intersection of physics and engineering, and its applications are widespread in science and technology. Let's start with a bit of history. In the 1940s, a British physicist named Sir Geoffrey Ingram Taylor first observed this radiation in experiments with cathode-ray tubes. However, it wasn't until the 1960s that researchers M. J. Stephen and G. A. Wilkerson formally described the phenomenon and named it after the American physicists E. M. Purcell and D. W. Smith. So, what are some applications of Smith-Purcell radiation? One exciting use is in particle accelerators, where it is utilized to measure the properties of charged particles. It can also be used in microscopy to image very small objects, and in the development of high-speed electronics and communications devices. To understand the concept of Smith-Purcell radiation more fully, it's essential to understand some related terms. A charged particle is any particle with an electric charge, while a periodic surface is a surface with repeating patterns or structures. The term electromagnetic wave refers to the waves that result when electric and magnetic fields interact with one another. Some of the most notable contributions to the field of Smith-Purcell radiation have come from Dr. David Attwood, a professor of physics at the University of California, Berkeley. Dr. Attwood has conducted extensive research on the topic, including the design and development of innovative imaging techniques for materials science. By exploring these topics and more, you can gain a deeper understanding of the exciting world of science and technology.

Have you ever wondered what lies beyond the pages of a closed book? Imagine being able to see the words on the pages without ever opening the cover. This is the exciting concept behind the technology developed by a group at MIT. Using terahertz waves, they can now read through closed books and uncover the hidden information inside. To do this, they had to overcome a series of challenges including the need for a radiation source that can penetrate the paper, the ability to distinguish between different pages, and the recognition of characters that are partially hidden. Learning about these academic concepts not only expands your knowledge of science and technology but also opens up new possibilities for studying antique documents and other important materials. Take the first step towards exploring the unseen world and discover the thrill of uncovering hidden information.

Have you ever wondered what the universe is made up of? Frank Close's Particle Physics: A Very Short Introduction is the perfect guide to explore the fundamental particles that make up our world. In this compelling book, Close provides a fascinating overview of the evolution of matter and the groundbreaking discoveries in particle physics. Whether you're a science enthusiast or just curious about the world around you, this book is sure to captivate your imagination and inspire you to delve deeper into the mysteries of the universe. Recommended for students and professionals alike, Frank Close's concise guide on particle physics is essential for those intrigued by the basic components forming our cosmos. Its reader-friendly language and captivating storytelling make it perfect for pupils in physics, astronomy, and engineering, as well as experts in the discipline. Additionally, it serves as an excellent reference for individuals passionate about science and technology or those inquisitive about their surroundings. Regardless of your experience level, this brief yet informative work will undoubtedly ignite your interest and motivate you to investigate the enthralling realm of particle physics.

Learning about lift and how planes fly may seem daunting, but it's a fascinating and important academic concept to explore. The force of lift is generated by the wings of a plane, which creates a difference in pressure above and below the wing. This pressure difference results in the upwards force of lift, allowing planes to take off and fly. While some explanations of lift have been debunked, the physics of fluid in motion remains constant. Understanding lift not only satisfies curiosity but also has practical applications in the field of aeronautics. By exploring this complex process, students can gain a deeper understanding of the world around them and potentially even contribute to advancements in the field.

Quantum computing is no longer a futuristic concept as researchers from MIT and other institutions have made a major breakthrough in quantum technology. They have developed a new superconducting parametric amplifier that achieves noise squeezing over a broad frequency bandwidth of up to 1.75 gigahertz while maintaining a high degree of squeezing, leading to faster and more accurate quantum systems. This breakthrough has significant implications for multiqubit systems and other metrological applications that demand extreme precision.

In our modern world, we are surrounded by electronic devices, from smartphones to laptops and beyond. But have you ever wondered about the foundation of these devices? Enter the silicon wafer, the building block of modern electronics. In this write-up, we'll explore the fascinating world of silicon wafers, from their origins to their use in modern technology. Silicon wafers are thin, circular slices of silicon that are used to create microchips, the tiny electronic components that power our devices. These wafers are made by growing a crystal of silicon and then slicing it into thin wafers. This process is known as "wafer fabrication," and it is a complex process that requires precision and expertise. One of the key figures in the development of silicon wafers is Gordon Moore, the co-founder of Intel. In 1965, Moore proposed what is now known as "Moore's Law," which states that the number of transistors that can fit on a microchip will double every 18-24 months. This law has held true for over 50 years and has been a driving force behind the incredible progress in electronics technology. Another influential figure is Andrew Grove, the former CEO of Intel. Grove was instrumental in making Intel a leader in the semiconductor industry, and he was a strong advocate for the importance of research and development in the field. Silicon wafers are used in a vast array of electronic devices, from smartphones and laptops to cars and even spacecraft. In fact, NASA's Mars rovers are powered by microchips built using silicon wafers. Without silicon wafers, our modern world as we know it would not be possible. Silicon wafers may seem like a small, insignificant component, but they are the foundation of the modern electronics industry. Learning about the origins and applications of silicon wafers can inspire students to explore the exciting world of electronics technology and pursue their interests in science and engineering.

Are you a fan of s'mores? Do you want to learn the science behind making the perfect gooey treat? In a quest for perfection, a writer turned to physics and thermodynamics to determine the ideal s'more technique. By considering the heat transfer from marshmallow to chocolate, the writer computed the specific heat and latent heat of melting of both ingredients, and conducted experiments to determine the optimal temperature for the marshmallow. The results? A marshmallow heated to 160°F produces the perfect s'more! This delicious experiment shows that science can be fun and tasty too.

Are you fascinated by the science behind materials? Do you enjoy exploring and testing the properties of different materials? If so, a career in Materials Engineering might be the perfect fit for you! As a Materials Engineer, you will work to develop and improve the materials used in a wide range of products, from electronics to construction materials. You will use your knowledge of chemistry and physics to analyze the properties of different materials and determine how they can be optimized for specific applications. One exciting aspect of this field is the potential for innovation. For example, Materials Engineers have been instrumental in the development of new materials like graphene, which has the potential to revolutionize industries such as electronics and aerospace. Typical duties in this field include conducting experiments and tests to analyze the properties of materials, designing and developing new materials, and collaborating with other engineers and scientists to improve existing products. There are also many areas of specialization within Materials Engineering, such as biomaterials, nanomaterials, and metallurgy. To become a Materials Engineer, you will typically need a bachelor's degree in Materials Science or a related field. Popular undergraduate programs and majors include Materials Science and Engineering, Chemical Engineering, and Physics. Helpful personal attributes for success in this field include strong analytical skills, attention to detail, and a passion for problem-solving. You should also have excellent communication skills, as you will often be working closely with teams of other engineers and scientists. Job prospects for Materials Engineers are strong, with the Bureau of Labor Statistics projecting a 2% increase in employment from 2019 to 2029. There are many potential employers in both the public and private sectors, including companies like Apple, Boeing, and NASA. In summary, a career in Materials Engineering offers the opportunity to work on cutting-edge projects, develop new and innovative materials, and contribute to a wide range of industries. If you have a passion for science and a desire to make a real impact, this might be the perfect career for you!

Invisibility may seem like a sci-fi concept, but it's not as far-fetched as you might think. Physicists have created experimental invisibility cloaks using specially-designed structures called "metamaterials". The key to cloaking is controlling the device's "refractive index", which changes the speed of light in the material. By steering light through in a gentle curve, a cloak made of metamaterials lets light bypass an object, making it invisible. Learning about invisibility cloaks can help you understand the properties of light, the concept of refractive index, and the use of metamaterials. It's an exciting and fascinating area of study that can inspire you to explore other scientific concepts and encourage you to think creatively about problem-solving.

If you've ever skipped stones across a body of water, you might be surprised to learn that there's a lot of science involved in making it work. The key to a good throw is spin, which stabilizes the stone and prevents it from tipping over and sinking. This same gyroscopic effect is what keeps the Earth spinning on its axis in space. Learning the technique of skipping stones can be a fun and engaging way to explore scientific concepts and develop your skills. By finding the right stone and mastering the right grip and throwing technique, you can achieve impressive results, like getting a stone to bounce 10, 15, or even 20 times. Not only is it a satisfying challenge, but it can also help you develop your understanding of physics and engineering.

Chocolate is not just an art, it's also a science. Discover how chocolatiers use the complex physics of chocolate to create the perfect texture, taste, and appearance. Learn about the six-phase polymorphic crystal structure of chocolate and how chocolatiers manipulate it through tempering. Explore the similarities between chocolate and carbon and how chocolatiers use their knowledge of physics to regulate the spread of flavor in their creations. Join master chocolatier Richard Tango-Lowy and physicist Joshua Erlich on a journey through the fascinating world of chocolate physics.

Researchers at MIT and other institutions have found a way to increase the emission of light from the interaction between photons and electrons by a hundredfold, with potential applications in modern technologies and scientific research.

Are you interested in the science behind figure skating? Elite figure skaters know physics at a visceral level in ways most of us don’t. For example, every twist, turn and leap begins with balance, which relies on keeping your center of mass aligned with a foot on the ice. But it’s not just the center of mass that matters in figure skating, the "moment of inertia" also plays a role. And for jumps, it amounts to three components: how much angular momentum you leave the ice with, how small can you make your moment of inertia in the air, and how much time you can spend in the air. Learn more about the physics of figure skating and the potential for quintuple jumps in the future.

Have you ever wondered how airplanes fly? It's more than just the shape of the wing, it's all about the physics of fluid in motion. The air we breathe is actually a fluid, and planes use this to their advantage to stay in the sky. Understanding the science behind how lift is generated can not only satisfy your curiosity but also give you an intellectual advantage. Learning about this can enhance your critical thinking and problem-solving skills, which can be valuable in many areas of your life. So, explore the science of flight and get ready to take off into a whole new world of knowledge!

Can we develop a mechanical method to detect explosives as effectively as bomb-sniffing dogs? Researchers from MIT Lincoln Laboratory are using a mass spectrometer to measure explosive vapors and understand the requirements for creating an operational explosive detection system that could work in tandem with the canine fleet to improve current airport security systems. The team's research is supported by the Department of Homeland Security's Detection Canine Program and the Next-Generation Explosives Trace Detection program. This innovative research could lead to a faster and more streamlined passenger experience and support the development of technology that remains resilient against evolving security threats

Physics is the study of the fundamental laws of nature, from the tiniest subatomic particles to the vast expanse of the universe. It is a field that seeks to understand the world around us and the forces that govern it. Physics is a fascinating and complex field that has a wide range of applications in our daily lives. One of the most exciting aspects of physics is the constant innovation and research that is taking place. From the development of quantum computing to the exploration of dark matter, there is always something new and exciting happening in the world of physics. Some of the most inspiring academic discourse in recent years has come from the likes of Stephen Hawking and Neil deGrasse Tyson, who have made complex physics concepts accessible and understandable to the general public. At undergraduate level, students can expect to study a range of modules, including mechanics, electromagnetism, thermodynamics, and quantum mechanics. These modules provide a solid foundation for further specialisation, such as astrophysics, biophysics, or particle physics. Real-life examples of the applications of physics include the development of medical imaging technologies, the creation of renewable energy sources, and the design of advanced materials for use in space exploration. With a degree in physics, there are a wide range of potential career paths available. Graduates can go on to work in research and development, engineering, finance, or education. Key industries for prospective future employment include aerospace, energy, and technology. Notable employers in these industries include NASA, SpaceX, and Google. To succeed in the field of physics, it is important to have a strong foundation in mathematics and a passion for problem-solving. Other helpful attributes include attention to detail, creativity, and the ability to think critically. With the right skills and interests, a degree in physics can be the start of an exciting and rewarding career.

Have you ever looked up at the sky and wondered how planes and rockets are able to soar through the air and reach the farthest corners of our galaxy? If you're curious about the science behind flight and space travel, then Aerospace Engineering might just be the perfect field of study for you! Aerospace Engineering is a fascinating discipline that combines principles of physics, mathematics, and materials science to design, build, and test aircraft, spacecraft, and other flying vehicles. From developing cutting-edge technologies for space exploration to creating more fuel-efficient and environmentally-friendly airplanes, the possibilities in this field are endless. One of the most exciting aspects of Aerospace Engineering is the constant innovation and research happening in the industry. From the development of supersonic planes to the exploration of Mars, there are always new and groundbreaking projects happening in this field. And with the rise of commercial space travel, the demand for skilled Aerospace Engineers is only set to increase. At the undergraduate level, students can expect to study a range of modules, including aerodynamics, propulsion, materials science, and control systems. There are also opportunities for specialisation in areas such as space systems engineering or aircraft design. But what can you do with a degree in Aerospace Engineering? The possibilities are vast and varied! Graduates can go on to work in the aerospace industry, designing and testing new aircraft and spacecraft for companies such as Boeing, Airbus, and NASA. They can also work in the defense industry, developing advanced technologies for military use. Other potential career paths include working in research and development, government agencies, or even starting their own aerospace companies. To succeed in Aerospace Engineering, it's helpful to have a strong background in mathematics, physics, and computer science. Attention to detail, problem-solving skills, and a passion for innovation are also important attributes for success in this field. So if you're ready to take your curiosity about flight and space to the next level, consider studying Aerospace Engineering at university. Who knows - you might just be the next person to design the next breakthrough technology in aviation or space exploration!