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!

Are you fascinated by the idea of designing and building aircraft that can soar through the skies at incredible speeds? Do you love the idea of working with cutting-edge technology and collaborating with a team of engineers and technicians to bring your ideas to life? If so, a career in Aerospace Manufacturing might be just what you're looking for! Aerospace Manufacturing is a field that involves designing, building, and testing aircraft and spacecraft components, systems, and structures. This field is constantly evolving, with new materials, technologies, and techniques being developed all the time. As an Aerospace Manufacturing professional, you'll be at the forefront of this exciting and dynamic industry, helping to create the next generation of aircraft and spacecraft. One of the most appealing aspects of a career in Aerospace Manufacturing is the variety of roles available. From designing and testing new aircraft components to managing production lines and overseeing quality control, there's something for everyone in this field. And with so many different areas of specialization to choose from, you can tailor your career to suit your interests and strengths. To get started in Aerospace Manufacturing, you'll typically need a degree in engineering or a related field. Popular undergraduate programs and majors include Aerospace Engineering, Mechanical Engineering, and Materials Science. You'll also need to have a strong foundation in math and science, as well as excellent analytical and problem-solving skills. Other helpful personal attributes for a career in Aerospace Manufacturing include attention to detail, creativity, and the ability to work well in a team. You'll need to be comfortable working with complex machinery and equipment, and be willing to continually learn and adapt as new technologies emerge. Job prospects in Aerospace Manufacturing are strong, with many exciting opportunities available around the world. Notable employers in this field include Boeing, Airbus, Lockheed Martin, and NASA, among others. And with the demand for new aircraft and spacecraft continuing to grow, the outlook for long-term career growth in Aerospace Manufacturing is very promising. So if you're looking for a career that combines your love of science, technology, and innovation, consider a career in Aerospace Manufacturing. With its exciting and ever-evolving nature, this field is sure to offer you a lifetime of challenging and rewarding work.

MIT engineers have developed ultralight fabric solar cells that can quickly and easily turn any surface into a power source. These durable, flexible solar cells are much thinner than a human hair and can be glued to a strong, lightweight fabric, making them easy to install on a fixed surface. They can be integrated onto the sails of a boat, adhered onto tents and tarps in disaster recovery operations, or applied onto the wings of drones to extend their flying range. This groundbreaking technology generates 18 times more power-per-kilogram than conventional solar panels, making it a promising solution to the present urgent need to deploy new carbon-free sources of energy.

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!

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.

Are you fascinated by the way machines work? Do you love tinkering with gadgets and gizmos? If so, then Mechanical Engineering might be the perfect field of study for you! Mechanical Engineering is a branch of engineering that deals with the design, manufacturing, and maintenance of mechanical systems. It's a broad field that covers everything from tiny micro-machines to massive industrial plants. And the best part? Mechanical engineers are responsible for some of the world's most awe-inspiring inventions! One of the most exciting aspects of Mechanical Engineering is the opportunity to work on cutting-edge research and innovations. For example, did you know that mechanical engineers are currently working on developing new materials that can withstand extreme temperatures and pressures? Or that they're designing robots that can perform tasks too dangerous for humans? The possibilities are endless! At the undergraduate level, you'll typically study a range of modules that cover topics such as mechanics, thermodynamics, and materials science. You'll also have the opportunity to specialize in areas like robotics, aerospace engineering, or renewable energy. And if you're interested in pursuing further education, there are plenty of graduate programs that can help you hone your skills and expertise. So, what kind of jobs can you get with a degree in Mechanical Engineering? The short answer is: almost anything! Mechanical engineers are in high demand across a wide range of industries, including aerospace, automotive, energy, and manufacturing. Some notable employers include NASA, Tesla, and Boeing. And if you're interested in working in the public sector, there are plenty of opportunities in areas like defense and infrastructure. To succeed in Mechanical Engineering, you'll need a strong foundation in math and science, as well as excellent problem-solving skills. You should also be curious, creative, and willing to take risks. But if you're up for the challenge, the rewards can be truly amazing! So, if you're looking for a career that's both challenging and rewarding, consider studying Mechanical Engineering. Who knows? You might just design the next big thing!

Are you fascinated by the design and construction of towering skyscrapers, magnificent bridges, and sprawling road networks? Do you want to be a part of the team that creates the infrastructure that shapes our world? If so, then studying Civil Engineering at the undergraduate level might be the perfect fit for you! Civil Engineering is a field of study that involves the design, construction, and maintenance of the built environment. This includes everything from buildings and bridges to roads and water systems. Civil Engineers use their technical skills and creativity to solve complex problems and create structures that are safe, efficient, and sustainable. In recent years, there have been several exciting innovations in the field of Civil Engineering. For example, researchers have developed new materials that are stronger and more durable than ever before. They have also used cutting-edge technology like drones and 3D printing to improve the efficiency of construction projects. Some of the most inspiring academic figures in the field include Dr. Henry Petroski, who has written extensively on the history of engineering failures, and Dr. Linda Hanagan, who is a leading expert on sustainable infrastructure. At the undergraduate level, students in Civil Engineering typically take courses in subjects like structural analysis, geotechnical engineering, and transportation planning. They may also have the opportunity to specialize in areas like environmental engineering or construction management. Some exciting examples of real-life Civil Engineering projects include the construction of the Burj Khalifa in Dubai, the Panama Canal expansion, and the redevelopment of the World Trade Center site in New York City. After graduation, there are a wide range of potential career paths for Civil Engineers. They may work for government agencies, construction firms, or consulting firms. Some popular industries for prospective employment include transportation, energy, and water resources. Notable potential employers include the US Army Corps of Engineers, Bechtel Corporation, and Arup Group. Other careers that may be relevant to Civil Engineering include architecture, urban planning, and environmental science. To succeed in this field of study, it is helpful to have strong math and science skills, as well as an interest in problem-solving and design. Effective communication and teamwork skills are also essential, as Civil Engineers often work on projects with large, interdisciplinary teams. If you're ready to take on the challenge of creating the infrastructure of the future, then studying Civil Engineering may be the perfect choice for you!

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.

Innovation and creativity are key academic concepts that can lead to groundbreaking inventions and discoveries. Douglas Engelbart, for example, invented the mouse, but it was Steve Jobs who saw its potential and brought it to the masses. Stephanie Kwolek discovered Kevlar, a material that is now used in a variety of products, but initially faced resistance from colleagues who didn't believe in her idea. Morton Heilig created the Sensorama, a 3D video machine, before the technology was ready for it. Wilson Greatbatch accidentally invented the pacemaker, saving millions of lives. These stories show that failure is not the end, but an opportunity to learn and try again. By exploring and developing their own ideas, students can contribute to society and make a difference in the world.

Are you fascinated by the inner workings of electronics and the power of electricity? Do you enjoy solving complex problems and designing innovative solutions? If so, a career in Electrical & Electronic Engineering might be the perfect fit for you! As an Electrical & Electronic Engineer, you will be responsible for designing, developing, and testing electrical equipment and systems. This includes everything from tiny microchips to massive power generators. You'll work with a team of other engineers to create cutting-edge technology that can change the world. One of the most exciting aspects of this field is the opportunity to work on projects that have a real impact on society. For example, you might design a new medical device that saves lives, or develop renewable energy sources that reduce our dependence on fossil fuels. The possibilities are endless! Some of the typical duties of an Electrical & Electronic Engineer include designing circuits and systems, testing prototypes, troubleshooting technical issues, and collaborating with other engineers and technicians. There are also many areas of specialization within this field, such as power systems, telecommunications, and robotics. To become an Electrical & Electronic Engineer, you'll need a strong foundation in math and science. Most engineers have at least a bachelor's degree in Electrical Engineering, Electronics Engineering, or a related field. Popular undergraduate programs include the Bachelor of Science in Electrical Engineering at MIT, the Bachelor of Engineering in Electronic Engineering at the University of Southampton, and the Bachelor of Electrical Engineering at the University of Toronto. In addition to technical skills, there are several personal attributes that can be helpful in this field. These include strong problem-solving skills, attention to detail, creativity, and the ability to work well in a team. Job prospects for Electrical & Electronic Engineers are strong, with a projected growth rate of 5% from 2019 to 2029. There are many potential employers in both the public and private sectors, including companies like Apple, Google, and Tesla. In addition, there are many government agencies and research institutions that hire Electrical & Electronic Engineers for a variety of projects. So if you're looking for a challenging and rewarding career that combines technical skills with real-world impact, consider a career in Electrical & Electronic Engineering. Who knows, you might be the one to design the next breakthrough technology that changes the world!

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!

MIT researchers have developed a 3D-printed miniature vacuum pump that could revolutionize the use of portable mass spectrometers. The pump is inexpensive, lightweight, and can operate at a low cost, making it ideal for use in remote locations or even in space. The unique design prevents fluid or gas from leaking while minimizing heat from friction during the pumping process, increasing the lifetime of the device. This breakthrough could lead to the monitoring of soil contamination in isolated parts of the world or geological survey equipment bound for Mars.

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.

Do you know there are over 1,300 shapes of pasta invented by the Italians? From hollow shapes to spiral ones, and even pasta shaped like astronauts and footballs, the possibilities are endless. Discover how different shapes pair with various sauces and how they are formed by hand, rolled into sheets, or extruded. Learn about innovative machines and technologies, such as 3D printing, that are changing the way we create pasta shapes. Join the pasta revolution and explore the world of pasta like never before!

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!

Have you ever wondered how cities are built? How bridges are constructed? How roads are designed? If you have, then a career in civil engineering might be the perfect fit for you! Civil engineering is a field that involves designing, building, and maintaining infrastructure such as roads, bridges, buildings, and water systems. Civil engineers use their knowledge of mathematics, physics, and materials science to create safe, efficient, and sustainable structures that meet the needs of society. As a civil engineer, you could work on a wide range of projects, from designing a new highway to creating a sustainable water treatment system. You could be responsible for ensuring the safety of thousands of people who use the structures you design and build. Some of the most exciting and meaningful aspects of civil engineering include the ability to make a real difference in people's lives. For example, you could design a new hospital that saves lives, or create a new transportation system that reduces traffic and pollution. You could also work on projects that help communities recover from natural disasters, such as earthquakes or floods. Typical duties of a civil engineer include designing structures, managing construction projects, and conducting inspections to ensure that structures are safe and meet building codes. Civil engineers can also specialize in areas such as geotechnical engineering, environmental engineering, or structural engineering. To become a civil engineer, you typically need a bachelor's degree in civil engineering or a related field. Popular undergraduate programs include civil engineering, environmental engineering, and structural engineering. Some civil engineers also pursue advanced degrees, such as a master's or doctorate, to specialize in a particular area of the field. Helpful personal attributes for civil engineers include strong analytical skills, attention to detail, and the ability to work well in a team. Civil engineers must also be able to communicate effectively with clients, contractors, and other stakeholders. Job prospects for civil engineers are strong, with the field projected to grow by 6% from 2018 to 2028. Civil engineers can find employment in a variety of sectors, including government agencies, consulting firms, and construction companies. Some notable employers include the U.S. Army Corps of Engineers, Bechtel Corporation, and Jacobs Engineering Group. In conclusion, a career in civil engineering offers the opportunity to make a real difference in people's lives, work on exciting and meaningful projects, and have a positive impact on the world around us. If you have a passion for math, science, and design, consider exploring this rewarding and fulfilling career path.

Product engineering is a fascinating and dynamic field that combines creative design thinking, advanced technology, and business acumen to produce innovative products that improve our lives. From smartphones to self-driving cars, the field of product engineering has revolutionized the way we live, work, and interact with the world around us. At its core, product engineering involves designing, developing, and refining products to meet the needs of users while ensuring their safety, efficiency, and sustainability. This interdisciplinary field draws on a range of disciplines, including mechanical engineering, electrical engineering, computer science, materials science, and human factors engineering. In recent years, product engineering has seen some exciting research and innovation. For example, 3D printing has transformed the way we prototype and manufacture products, while artificial intelligence and machine learning have enabled us to create smarter, more responsive products. Notable academic figures in the field include Don Norman, who has written extensively on the intersection of design and human behavior, and Clayton Christensen, who coined the term "disruptive innovation" and has had a profound impact on the way we think about product development. At the undergraduate level, students can expect to take a range of courses that cover the fundamentals of product engineering, including design thinking, prototyping, and manufacturing. Typical majors and modules include product design, manufacturing processes, materials science, and computer-aided design. Students can also explore areas of further specialization such as robotics, mechatronics, or product management. Product engineering opens up a wealth of career opportunities, including roles in product design, development, and management, as well as in fields such as quality control, supply chain management, and user experience. Key industries for prospective employment include technology, automotive, and consumer goods, with notable employers such as Apple, Tesla, and Procter & Gamble. To succeed in this field, students should have a strong foundation in science, technology, engineering, and math (STEM), as well as excellent problem-solving skills, attention to detail, and creativity. They should also be able to work well in teams, communicate effectively, and be comfortable with uncertainty and change.

MIT researchers have developed a wake-up receiver that is less than one-tenth the size of previous devices and consumes only a few microwatts of power. The receiver also incorporates a built-in authentication system that protects the device from a certain type of attack that could quickly drain its battery. The device uses terahertz waves, which are about one-tenth the length of radio waves, enabling it to be used in miniaturized sensors and microrobots that monitor environmental changes in areas that are either too small or hazardous for other robots to reach.

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.

MIT researchers have developed an AR headset, X-AR, that gives the wearer X-ray vision to locate and retrieve hidden items. Using RF signals and RFID tags, the headset directs the user to the hidden object, which shows up as a transparent sphere in the AR interface. X-AR could revolutionize e-commerce warehouses and manufacturing facilities by quickly finding items on cluttered shelves or buried in boxes. The research will be presented at the USENIX Symposium on Networked Systems Design and Implementation.