Are you interested in using your love for science and technology to make a real difference in people's lives? If so, a career in Biomedical Engineering might be the perfect fit for you! Biomedical Engineering is a field that combines biology, medicine, and engineering to design and create medical devices, equipment, and software that help improve the quality of life for patients. Biomedical Engineers are responsible for developing life-saving technologies such as artificial organs, prosthetic limbs, and medical imaging systems that help doctors diagnose and treat diseases. As a Biomedical Engineer, you'll have the opportunity to work on projects that directly impact people's health and wellbeing. For example, you could design a new type of pacemaker that helps regulate heartbeats, or create a prosthetic limb that allows someone to walk again. The possibilities are endless! Typical duties of a Biomedical Engineer include researching and developing medical products, designing and testing prototypes, overseeing the manufacturing process, and working with doctors and other healthcare professionals to ensure that products meet their needs. Biomedical Engineers can also specialize in areas such as tissue engineering, biomaterials, or medical imaging. To become a Biomedical Engineer, you'll need a strong background in math and science, as well as a degree in Biomedical Engineering or a related field such as Electrical Engineering, Mechanical Engineering, or Computer Science. Popular undergraduate programs and majors include Biomedical Engineering, Bioengineering, and Medical Engineering. Helpful personal attributes for a career in Biomedical Engineering include creativity, problem-solving skills, attention to detail, and a passion for helping others. Job prospects for Biomedical Engineers are excellent, with the field projected to grow much faster than the average for all occupations. Biomedical Engineers can work for a variety of employers, including medical device companies, hospitals, research labs, and government agencies. Some notable employers in the field include Medtronic, Johnson & Johnson, General Electric, and the National Institutes of Health. In summary, a career in Biomedical Engineering is an exciting and rewarding way to use your skills and knowledge to make a real difference in people's lives. If you're interested in combining your love for science and technology with a desire to help others, then Biomedical Engineering might be the perfect career for you!

Are you interested in the future of prosthetics and robotics? Check out this fascinating article from MIT Technology Review about a soft electronic skin that could revolutionize the way people with prosthetics interact with their surroundings. The skin, which is thin and stretchable, contains sensors that measure pressure and temperature, sending electrical signals to an implanted electrode in the brain. The research team from Stanford University hopes this technology could lead to better prosthetics and even robots that can feel human-like sensations. Read the full article to learn more!

Did you know that the oldest glue in the world is over 8,000 years old and comes from a cave near the Dead Sea? Ancient people used this glue, made from a mixture of animal bone and plant materials, to waterproof baskets and construct utensils. Today, we have enough types of tape and glue to build and repair almost anything. But have you ever wondered what gives glue and tape their stickiness? Adhesives can be made from synthetic molecules or natural proteins and carbohydrates. In order to work, glue and tape need both adhesive bonds and cohesive bonds. Glue is stronger than tape in terms of absolute strength of adhesive bonds, but no single adhesive works well in all circumstances. Engineers weigh similar factors all the time. Choosing the right glue to withstand the heat inside an engine is a matter of life and death. And though the strength of duct tape's adhesive bonds can't compete with those of epoxy glues, tape does have the advantage of instantaneous stickiness in an emergency. Learning about adhesives can help you understand how things are constructed and repaired, and can even save lives in certain situations.

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.

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.

Concrete is the most widely used construction material in the world, but it has a weakness: it's prone to catastrophic cracking that costs billions of dollars to repair each year. However, scientists have discovered ways to create concrete that can heal itself. By adding hidden glue or bacteria and fungi spores to the concrete mix, cracks can be repaired up to almost 1mm wide. This technique has the potential to make concrete more resilient and long-lasting, which could drastically reduce the financial and environmental cost of concrete production. Learning about the science behind concrete and its potential for self-healing can not only be intellectually stimulating but also practically beneficial for the future of construction. Imagine being part of the solution to creating more sustainable and durable infrastructure for our cities.

Biomimicry is a fascinating and innovative concept that is changing the way we approach technology and sustainability. Janine Benyus takes readers on a journey through the natural world, where scientists and inventors are drawing inspiration from nature's most successful ideas to revolutionize our world. From creating materials to healing ourselves, Biomimicry shows how we can learn from the genius of the animal kingdom. This book is a must-read for anyone interested in the future of our planet and the exciting possibilities that lie ahead. Recommended for students of biology, engineering, and environmental studies, Biomimicry offers a fresh perspective on how we can learn from nature to solve some of the world's most pressing problems. Professionals in the fields of medicine, architecture, and technology will also find inspiration in the innovative ideas presented in this book. Additionally, anyone interested in sustainability, conservation, and the future of our planet will appreciate the creative solutions and exciting possibilities explored in Biomimicry. Overall, this book is a valuable resource for anyone looking to explore new and innovative approaches to problem-solving.

Do you ever wonder what goes into creating your favorite snacks or how your favorite restaurant creates their signature dishes? If you're passionate about food and curious about the science behind it, then studying Food Science at university could be the perfect fit for you! Food Science is a multidisciplinary field that combines chemistry, biology, nutrition, and engineering to study the physical, chemical, and biological properties of food. This field of study is all about understanding how food is processed, preserved, and packaged, as well as how it affects the human body. One of the most exciting aspects of Food Science is the potential for innovation and discovery. Researchers in this field are constantly working on new ways to improve the taste, texture, and nutritional value of food. For example, did you know that Food Scientists have developed plant-based meat alternatives that look, taste, and even "bleed" like real meat? Or that they've created edible packaging made from seaweed that could revolutionize the way we package and transport food? Some of the most influential figures in Food Science include Harold McGee, who wrote the seminal book "On Food and Cooking: The Science and Lore of the Kitchen," and Hervé This, who is credited with being one of the pioneers of Molecular Gastronomy. At the undergraduate level, typical majors and modules in Food Science include food chemistry, food microbiology, food engineering, and food safety. Students can also specialize in areas such as product development, sensory analysis, and food packaging. But what can you do with a degree in Food Science? The possibilities are endless! Graduates can go on to work in a variety of industries, including food and beverage manufacturing, food safety and regulation, and product development. Some notable employers in this field include Nestle, Kraft Heinz, and PepsiCo. If you're considering studying Food Science, it's important to have a strong foundation in science and math. Additionally, having a passion for food and an interest in sustainability and health can be helpful attributes to succeed in this field. So if you're ready to combine your love of food with your passion for science, then studying Food Science could be the perfect path for you!

Do you have a passion for food and a curious mind? Do you enjoy conducting experiments and discovering new things? Then a career in Food Science might be the perfect fit for you! Food Science is the study of the physical, chemical, and biological properties of food, and how they affect its quality, safety, and nutritional value. It's a fascinating field that combines elements of biology, chemistry, and engineering to create new and innovative food products that are both delicious and healthy. As a Food Scientist, you could be involved in a variety of exciting projects. For example, you might work on developing new food products that are low in fat, sugar, or salt, or that contain more fiber or protein. Or you might be responsible for ensuring the safety of food products by testing them for harmful bacteria or other contaminants. You could also work in the field of sensory science, where you would use your knowledge of taste, smell, and texture to help create foods that are more enjoyable to eat. The duties of a Food Scientist can vary depending on their area of specialization. Some Food Scientists work in research and development, where they design and test new food products. Others work in quality control, where they ensure that food products meet certain standards of safety and quality. Still others work in regulatory affairs, where they ensure that food products meet government regulations and guidelines. To become a Food Scientist, you'll typically need a Bachelor's degree in Food Science, Nutrition, or a related field. There are many excellent undergraduate programs available, such as the Food Science program at Cornell University or the Nutrition and Food Science program at the University of Alberta. In addition to a strong academic background, there are several personal attributes that can be helpful for a career in Food Science. These include a keen attention to detail, excellent problem-solving skills, and a creative and curious mind. The job prospects for Food Scientists are excellent, with many opportunities available in both the public and private sectors. Some notable employers include the United States Department of Agriculture, Nestle, and PepsiCo. In addition, there is a growing demand for Food Scientists in developing countries, where there is a need for new and innovative food products that can help address issues such as malnutrition and food insecurity. So if you're looking for a career that combines your love of food with your passion for science, consider exploring the exciting field of Food Science!

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!

Are you fascinated by the power of the atom? Do you want to be part of the solution to the world's energy crisis? Then Nuclear Engineering might just be the field for you! Nuclear Engineering is a dynamic and exciting field that involves the study of nuclear reactions and their applications. From designing nuclear power plants to developing radiation treatments for cancer, Nuclear Engineering has a wide range of real-world applications that can make a meaningful impact on society. In recent years, there have been many exciting developments in Nuclear Engineering. For example, scientists have been working on developing nuclear fusion as a clean and sustainable energy source. There have also been exciting advancements in the field of nuclear medicine, including the development of targeted radiation therapies for cancer. At the undergraduate level, typical majors in Nuclear Engineering include courses in nuclear physics, reactor design, and radiation protection. Students can also choose to specialize in areas such as nuclear materials or nuclear fuel cycle. The potential career paths for graduates in Nuclear Engineering are diverse and exciting. Graduates can find work in industries such as nuclear power generation, nuclear medicine, and nuclear waste management. Some notable employers in the field include the International Atomic Energy Agency, General Electric, and the US Department of Energy. To succeed in Nuclear Engineering, students should have a strong background in mathematics and physics. They should also be curious, analytical, and detail-oriented. So, if you're ready to explore the fascinating world of nuclear reactions and their applications, consider studying Nuclear Engineering at the undergraduate level. The possibilities are endless!

Plastics have become ubiquitous in our daily lives, but few of us know the history behind this versatile material. The first plastic was created in 1863 by an American named John Wesley Hyatt, who invented celluloid, made from cellulose found in wood and straw. This discovery led to a cascade of new plastics, including bakelite, polystyrene, polyvinyl chloride, acrylics, and nylon. Plastics have replaced other materials like wood, glass, and fabric in furniture, clothing, and packaging. While plastics have brought convenience and cost-effectiveness, they have also created staggering environmental problems. Many plastics are made of nonrenewable resources, and plastic packaging was designed to be single-use, but some plastics take centuries to decompose, creating a huge buildup of waste. By learning about plastics, students can understand how science and innovation have shaped our world, and they can explore ways to address the environmental problems associated with plastic use.

Are you fascinated by the world of science and engineering? Do you enjoy exploring the properties of different materials and their potential applications? If so, then studying Materials Science at university undergraduate level might just be the perfect fit for you! Materials Science is an interdisciplinary field that combines the principles of physics, chemistry, and engineering to investigate the properties of different materials and develop new materials with specific properties. This field of study is essential in the development of new technologies, from the creation of lighter and stronger materials for aerospace applications to the development of new medical implants that can better integrate with the human body. One of the most exciting aspects of Materials Science is the wide range of research and innovation that is taking place in this field. From the development of new materials for energy storage and conversion to the creation of biomaterials for use in tissue engineering, there is no shortage of fascinating research topics to explore. At the undergraduate level, Materials Science majors can expect to take a variety of modules that cover topics such as materials characterization, materials processing, and materials design. Students will also have the opportunity to specialize in areas such as nanomaterials, biomaterials, and electronic materials, among others. With a degree in Materials Science, graduates can look forward to a range of exciting career opportunities. Some of the key industries for prospective future employment include aerospace, automotive, electronics, and healthcare. Notable employers in these industries include companies such as Boeing, Tesla, Intel, and Johnson & Johnson, among many others. To succeed in this field of study, students should possess a strong foundation in mathematics and physics, as well as a keen interest in materials science and engineering. Additionally, strong problem-solving skills, attention to detail, and a passion for innovation are all essential attributes for success in this field. So, if you're looking for a challenging and rewarding field of study that combines the principles of science and engineering with real-world applications, then look no further than Materials Science!

Are you aware that over 2 billion people globally drink water contaminated with disease-causing microbes? Stanford University and SLAC National Accelerator Laboratory have developed a low-cost, recyclable powder that can kill thousands of waterborne bacteria per second when exposed to ordinary sunlight. This discovery could be a significant breakthrough for the nearly 30 percent of the world's population without access to safe drinking water. The results of their study are published in Nature Water.

Discover the science behind fried foods with a simple experiment that tests oil uptake, texture, and taste. Led by Fred Shih of the USDA, this team of professionals found surprising differences between beer-battered and water-based batters. Explore the world of food science and learn whether your future lies in the lab or at the bar.

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?

Batteries are a crucial part of our modern lives, powering everything from our smartphones to our cars. But the production and disposal of batteries have significant environmental impacts, from toxic chemicals and heavy metals to greenhouse gas emissions. Fortunately, there are sustainable options and alternatives to batteries that can help mitigate these negative effects. One such option is kinetic energy, which converts motion into electricity. For example, the piezoelectric effect harnesses energy from pressure, while the triboelectric effect converts friction into electricity. Another alternative to batteries is supercapacitors, which store energy in an electric field rather than a chemical reaction. They charge and discharge quickly and have a longer lifespan than traditional batteries. These sustainable options and alternatives to batteries are being researched and developed by leading academics in the field of materials science and engineering. Dr. Jennifer Lewis, a professor of biologically inspired engineering at Harvard University, is leading a team that is working on creating 3D-printed energy storage devices using a hydrogel-based ink. Meanwhile, Dr. Yi Cui at Stanford University is researching how to improve the energy density and safety of solid-state batteries. By exploring academic topics like materials science and engineering, students can learn about the properties of different materials and how they can be manipulated to create sustainable technologies. You can also learn about the environmental impact of technology and how sustainable alternatives can mitigate these effects. In conclusion, sustainable alternatives to batteries offer exciting opportunities for innovation and environmental sustainability. By exploring academic topics related to these technologies, high school students can gain a deeper understanding of the scientific principles behind sustainable energy and contribute to a more sustainable future.

As the world faces increasingly urgent environmental challenges, there is a growing need for sustainable solutions across all industries, including healthcare. Biodegradable implants are one such solution, with the potential to revolutionize the medical field while minimizing its environmental impact. Unlike traditional implants made from non-biodegradable materials, such as metal or plastic, biodegradable implants are designed to break down over time, leaving no harmful residue behind. This means they not only benefit the patient, but also the environment. One area where biodegradable implants are particularly promising is in orthopedic surgery. According to a study published in the Journal of Orthopaedic Research, biodegradable implants made from natural materials such as collagen and silk have shown promise in promoting bone growth and healing. Leading academics in the field include Dr. Jennifer Elisseeff, a professor of biomedical engineering at Johns Hopkins University, whose research has focused on developing biodegradable scaffolds for tissue engineering, and Dr. Lisa E. Freed, a professor of materials science and engineering at the University of California, Berkeley, who has worked on developing biodegradable implants for orthopedic applications. But the potential of biodegradable implants extends beyond orthopedics. They can also be used in drug delivery, wound healing, and other areas of medicine. In fact, researchers at the University of Cambridge are currently developing biodegradable implants for use in cancer treatment. As promising as biodegradable implants are, they are not without their challenges. For example, they must be designed to break down at just the right rate, neither too quickly nor too slowly, in order to ensure optimal healing. But with continued research and development, biodegradable implants have the potential to transform the medical field for the better.

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

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.