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.

The periodic table may seem like just another table of information, but it is so much more. It is a tool that scientists use to understand the world around us. By organizing all the chemical elements in order by atomic number, the periodic table creates a recurring pattern of properties called the periodic law. This allows us to predict the behavior of elements we haven't even discovered yet! Through the history of the periodic table, we can see how scientific discoveries and technological advancements build upon one another. Learning about the periodic table not only expands your scientific knowledge but also helps you develop analytical and critical thinking skills. By exploring this fascinating topic, you may even be inspired to pursue a career in science and help advance our understanding of the world.

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.

MIT physicists have observed a resonance in colliding ultracold molecules for the first time, shedding light on the mysterious forces that drive molecules to chemically react. The team found that a cloud of super-cooled sodium-lithium (NaLi) molecules disappeared 100 times faster than normal when exposed to a very specific magnetic field, indicating that the magnetic field tuned the particles into a resonance, driving them to react more quickly than they normally would. These findings suggest that scientists could one day harness particles’ natural resonances to steer and control certain chemical reactions.

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.

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!

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

Teflon, a material that doesn't stick to anything, was stumbled upon accidentally in 1938 by a chemist named Roy Plunkett. Teflon's properties make it perfect for things that need to be slippery, chemical-resistant, or waterproof, which means it has a lot of applications. It can be found all over the place, from raincoats to industrial ball bearings to artificial joints. The incredible properties of PTFE, the chemical name for Teflon, come from its molecular structure. It's a polymer, meaning it's made of long chains of repeating units of atoms strung together. PTFE has tight carbon-fluorine bonds that ignore the normal, intermolecular forces that help substances stick to each other. Even the famously adhesive feet of geckos usually can't get a grip on it. Learning about the properties of materials like Teflon can inspire independent exploration of science and engineering, which can lead to exciting career opportunities in fields like materials science and chemical engineering.

The future of resource extraction lies in space exploration. Asteroids, leftovers from the formation of the planet 4.5 billion years ago, contain rare and precious materials such as platinum, iron, and nickel. The mining industry on Earth is harmful to the environment and people, but space mining could provide a clean and sustainable alternative. Cheaper space travel is necessary to make asteroid mining profitable, and scientists and economists are working on solutions such as electric spaceships. Once a stable asteroid is secured, space mining and processing equipment can extract valuable materials through a process that uses giant mirrors to focus sunlight and heat up asteroid rock. Even a small percentage of a single asteroid's mass in precious metals could be worth billions of dollars. The benefits of space exploration and asteroid mining are vast, and the possibilities for discovery and innovation are endless.

Are you interested in using your creativity and problem-solving skills to make a positive impact on the world? Then a career in chemical engineering might be right up your alley! Chemical engineering is a field that combines knowledge of chemistry, physics, and mathematics to design and develop new products and processes. As a chemical engineer, you could work in a variety of industries, including pharmaceuticals, energy, food and beverage, and more. For example, you might work on developing new medicines to treat diseases, or on designing more efficient and sustainable ways to produce energy. One exciting aspect of chemical engineering is the potential for innovation and discovery. For example, chemical engineers have been instrumental in developing new materials like graphene, which has the potential to revolutionize industries from electronics to transportation. In terms of day-to-day duties, chemical engineers might be involved in everything from designing experiments and analyzing data to overseeing production processes and troubleshooting problems that arise. There are also many areas of specialization within the field, such as materials science, process design, and environmental engineering. To become a chemical engineer, you'll typically need to earn a bachelor's degree in chemical engineering or a related field. Some popular undergraduate programs include the chemical engineering programs at MIT, UC Berkeley, and the University of Texas at Austin. In addition to technical knowledge, there are a few personal attributes that can be helpful in a career in chemical engineering. These include strong problem-solving skills, attention to detail, and the ability to communicate complex ideas clearly and effectively. As for job prospects, chemical engineering is a field with plenty of opportunities for growth and advancement. Some notable employers include companies like Procter & Gamble, ExxonMobil, and DuPont, as well as government agencies like the Environmental Protection Agency and the Department of Energy. In conclusion, if you're interested in using your scientific knowledge to make a difference in the world, a career in chemical engineering might be the perfect fit for you. With plenty of opportunities for innovation and growth, this field offers the chance to make a real impact on society and the environment. So why not explore this exciting career path today?

Discover the fascinating story of how a broken soda fountain led to the creation of ICEE, the science behind its slushy texture, and the complex chemistry of its flavor syrup. Explore the avalanche-like physics of how ICEE solidifies and the Joules-Thomson effect that makes it puff up. Learn about the inventor, Omar Knedlik, and how his entrepreneurial spirit led to the mass production of his invention, eventually renamed Slurpee by 7-Eleven.

Are you interested in exploring the world of artificial intelligence (AI) and its impact on our daily lives? Look no further than Stanford University's latest research on energy-efficient memory storage for AI training. In a recent breakthrough, researchers at Stanford found a material that could revolutionize the way we store data using electron spin directions, resulting in faster and more efficient processing. This new memory storage method, known as spin orbit torque magnetoresistive random access memory (SOT-MRAM), could enable AI training on devices like your phone or smartwatch. Check out the full article in Nature Materials to learn more!

Lightning is a fascinating natural phenomenon that has puzzled scientists for over 260 years. While the basics of lightning formation are known, scientists still don't fully understand how it forms. Lightning is like a zap of static electricity but on a much larger scale. It occurs when positive and negative charges build up in storm clouds, and a spark jumps between these areas. Learning about the science behind lightning formation can be intellectually stimulating and practically useful, as it can help us understand and prepare for thunderstorms. While there are still many unanswered questions, exploring this topic through reading and self-directed projects can be an exciting endeavor for high school students curious about the world around them.

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!

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.

Have you ever heard of the field of nanotechnology? It's a rapidly growing and exciting field that is revolutionizing the way we live, work, and play. Nanotechnology is the study and manipulation of materials on a molecular or atomic scale, and it has the potential to transform everything from medicine to electronics. Imagine creating tiny robots that can swim through your bloodstream and target cancer cells, or developing ultra-light and ultra-strong materials for airplanes and cars. These are just a few examples of the amazing possibilities that nanotechnology offers. As a nanotechnologist, you would work with these tiny materials to create new products and technologies. You might design and develop new materials, work on improving existing ones, or create entirely new devices and systems. You could work in a variety of fields, from medicine to electronics to energy. Typical duties in nanotechnology might include conducting experiments, analyzing data, designing and building prototypes, and collaborating with other scientists and engineers. There are also many areas of specialization within nanotechnology, such as nanoelectronics, nanobiotechnology, and nanomaterials. To get started in this field, you'll need a strong background in science and engineering. Many nanotechnologists have degrees in materials science, chemistry, physics, or electrical engineering. Some popular undergraduate programs and majors include nanotechnology engineering, materials science and engineering, and chemical engineering. In addition to technical skills, there are certain personal attributes that can be helpful in this field. These might include a strong attention to detail, excellent problem-solving skills, and a creative and innovative mindset. The job prospects for nanotechnologists are excellent, with many exciting opportunities available in both the public and private sectors. Some notable employers in this field include IBM, Intel, and Samsung, as well as government agencies such as NASA and the National Institutes of Health. So if you're looking for a career that is both challenging and rewarding, consider exploring the field of nanotechnology. Who knows what amazing discoveries and inventions you might be a part of in the future!

"Rocks are becoming rocks again!" says chemist Peter Psarras from the Clean Energy Conversions Lab (CECL) at the University of Pennsylvania. Psarras and his team are turning waste from industrial mines into magnesium carbonate through a carbon-neutral and inexpensive process, with the goal of storing CO2. With five partner mines, the CECL lab, funded by the Kleinman Center for Energy Policy and the School of Engineering and Applied Science, is exploring the environmental potential of mine tailings and determining the scalability of the carbonation process. Join Psarras and the CECL in their mission to tap into the "moved mountain" of waste and be inspired by their cutting-edge technology.

Researchers have powered a microprocessor for a year using blue-green algae and ambient light! This system, comparable in size to an AA battery, has the potential to be a reliable and renewable way to power small devices. The growing Internet of Things needs power, and this system generates energy instead of simply storing it like batteries. The algae system is made of common and recyclable materials, making it easily replicable.

Are you ready to explore the cutting-edge world of quantum computing? IBM has announced plans to build a 100,000-qubit machine within the next decade, partnering with the University of Tokyo and the University of Chicago in a $100 million dollar initiative. This technology could potentially tackle pressing problems that no standard supercomputer can solve, opening the door to a swath of classically impossible computing tasks. Don't miss out on this exciting development in the field of quantum computing! Read more about it in the MIT Technology Review.

Are you fascinated by cars and how they work? Do you dream of designing the next generation of vehicles that will take the world by storm? If so, then Automotive Engineering might be the perfect field of study for you! Automotive Engineering is an exciting and dynamic field that combines elements of mechanical, electrical, and materials engineering to create the vehicles of tomorrow. From designing engines and transmissions to improving fuel efficiency and safety features, Automotive Engineering covers a wide range of fascinating topics that will keep you engaged and inspired throughout your studies. One of the most interesting aspects of Automotive Engineering is the constant innovation and research that is taking place in the field. From developing new materials that are stronger and more lightweight to improving hybrid and electric vehicle technology, there is always something new and exciting happening in the world of Automotive Engineering. Some of the most well-known figures in the field include Ferdinand Porsche, who designed the iconic Porsche 911, and Elon Musk, who is leading the charge in developing electric and autonomous vehicles through his company Tesla. At the undergraduate level, students can expect to study a range of modules that cover topics such as vehicle dynamics, engine design, and materials science. There are also opportunities for further specialisation in areas such as aerodynamics, alternative fuels, and vehicle safety. After graduation, there are a wide range of potential career paths available to Automotive Engineering graduates, including roles in vehicle design, research and development, and manufacturing. Some of the most notable employers in the field include Ford, General Motors, and BMW, as well as government agencies such as NASA and the Department of Defense. To succeed in Automotive Engineering, students should have a strong foundation in math, physics, and chemistry, as well as an interest in mechanical and electrical systems. They should also possess strong problem-solving skills and be able to work well in a team environment. So if you're ready to take your love of cars to the next level, consider studying Automotive Engineering and be a part of shaping the future of transportation!