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As a society, we rely heavily on oil, but this addiction has led to environmental disasters like oil spills. However, nature has a way of cleaning up after us. Microbes, tiny bacteria that evolved to take advantage of oil and gas seeping from the sea floor, have been eating up oil spills for eons. In fact, a big bloom of microbes ate most of the 4.1 million barrels of oil spilt by BP's Macondo well in the Gulf of Mexico. These microbes are not only oil-eaters, but they also eat plastics, making them a potential solution to the Great Pacific Garbage Patch. Scientists are working on enhancing microbes' ability to eat oil and plastic, which could help us clean up our messes faster. Learning about these microbes and how they can benefit us is not only intellectually stimulating, but it also has practical implications for our planet's health.
Can a single cell's physical properties predict how tall a tree can grow? MIT Professor Ming Guo's research in cell mechanics reveals how a cell's physical form can influence the growth of an entire organism, including disease such as cancer. With his interdisciplinary work in physics, mechanical engineering, and cell biology, Guo aims to engineer materials for biomedical applications.
The search for alien life in the universe is an intriguing quest that has captivated the attention of many. The possibility of life existing in various forms and how it could have developed is a topic that continues to spark curiosity. Scientists have been working on a theory of panspermia, which suggests that life exists throughout the universe and can be transported through space from one location to another. Microorganisms, such as archaea and bacteria, have been able to modify themselves to adapt to a vast range of conditions, making them incredibly adaptable. These extremophiles can survive in the most extreme conditions that Earth has to offer, making them the most oven-ready organisms to survive and potentially colonize the hostile environments of other planets and moons. Learning about these academic concepts not only expands our knowledge of the universe but also allows us to understand the adaptability of life and its possibilities.
Plastics are everywhere, and most of them never biologically degrade. This is a major problem for our environment, as plastic waste pollutes natural ecosystems for centuries. Fortunately, there are microbes that may be able to help us solve this growing problem. Scientists have discovered bacteria, also known as plastivores, that contain enzymes capable of breaking down PET polymers, a common type of plastic. However, we still need ways to biologically degrade all the other types of plastic, including abundant PEs and PPs. Researchers are looking for more heat-tolerant plastivores in the planet's most hostile environments and engineering better plastivorous enzymes in the lab. As students, you have the opportunity to learn about this important issue and contribute to finding solutions. By exploring the science behind plastic degradation, you can gain a deeper understanding of how to protect our environment and create a more sustainable future.
Did you know that almost everything around you is being eaten by tiny organisms called microbes? These hordes of bacteria, archaea, and fungi have evolved to break down tough organic material into digestible nutrients. However, there is one material that almost no microbes can biodegrade: plastics. This is because most plastics have only been around since the 1950s, so most microbes haven't had time to evolve enzymes to digest them. As a result, plastics just turn into countless, tiny, indigestible pieces that pollute the environment. However, researchers have discovered microbes that may be able to take a bite out of this growing problem, creating super-enzymes that could break down plastics faster. By exploring the science behind microbes and biodegradability, you can learn how to become part of the solution to this global issue. Not only will you expand your knowledge, but you will also contribute to creating a cleaner, healthier planet.
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.
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.
Do you feel a deep connection with the sea and its inhabitants? Do you find yourself daydreaming about what lies beneath the ocean's surface? If so, a career in oceanography might be perfect for you! As an oceanographer, you'll be studying the ocean, its physical and biological properties, and how it interacts with the planet. You'll work to understand everything from the temperature and salinity of the water, to the movement of currents, the behavior of marine life, and how humans impact the ocean. One of the most appealing aspects of a career in oceanography is the opportunity to work on important environmental issues. For example, you could study how climate change is impacting the ocean and marine life, work to protect endangered species, or research ways to develop sustainable fishing practices. There are also countless fascinating and inspiring examples of real-life oceanographers making a difference. For instance, Sylvia Earle is a marine biologist and explorer who has led more than 100 deep sea expeditions and been instrumental in the creation of marine protected areas. Jacques Cousteau, an oceanographer and explorer, was a pioneer in underwater filmmaking and worked to raise awareness about ocean conservation. As an oceanographer, you'll typically be conducting research and collecting data, analyzing samples in a laboratory setting, and communicating your findings to colleagues, stakeholders, and the public. You could choose to specialize in one of several areas, including biological oceanography, chemical oceanography, physical oceanography, or marine geology. There are also related fields like marine biology, marine ecology, and ocean engineering. To become an oceanographer, you'll typically need at least a bachelor's degree in a relevant field, such as marine biology, oceanography, or environmental science. Many universities offer specialized programs, such as the Marine Science program at the University of Miami or the Oceanography program at the University of Washington. Additionally, internships and field experience can be highly beneficial for gaining practical skills and connections in the field. Helpful personal attributes for an oceanographer include a passion for the ocean and its inhabitants, strong analytical skills, and a willingness to work in a team environment. Additionally, it's important to have good communication skills, as you'll be communicating complex scientific concepts to a variety of audiences. The job prospects for oceanographers are good, with an expected job growth of 7% from 2020 to 2030. There are many potential employers in both the public and private sectors, including government agencies like NOAA (the National Oceanic and Atmospheric Administration) and private companies like Shell or ExxonMobil. You could also work for non-profits like the Ocean Conservancy or research institutions like Woods Hole Oceanographic Institution.
As a student, you might have wondered why your experiments didn't go as planned, or you struggled to find answers to your scientific questions. Here's where the scientific method comes in! The scientific method is a step-by-step process used to investigate and solve problems. By following the six steps - ask, research, form a hypothesis, experiment, analyze, and conclude - you can find solutions to your problems and answer your scientific queries. Learning the scientific method not only helps you solve everyday problems but also enhances your critical thinking and analytical skills, which can benefit you in your academic and personal life. Try it out and unleash your inner scientist!
Discover the secrets behind the remarkable hydrodynamic performance of shark skin and how it's inspiring the design of bioinspired robots and materials!
Water is one of the most fascinating substances in the universe. Every molecule of water on Earth has existed for billions of years, cycling through rocks, air, animals, and plants. Water doesn't follow the normal rules of chemistry, expanding when it freezes and floating on itself, enabling complex life to survive on our planet. Hot water freezes faster than cold, and water molecules can float upwards, against the force of gravity. This strange behavior has been very useful, allowing oxygen and nutrients to reach the edges of our brain and plants to move water from deep below the ground to nourish their leaves. Our solar system is drowning in water, and where there's water, there could be life. Learning about the properties of water can help students appreciate the remarkable nature of this colorless, featureless, and tasteless substance that breaks so many rules of chemistry.
Understanding the science behind the changing colors of leaves in the fall is not only fascinating but also important for our understanding of the natural world around us. The process is triggered by less daylight, causing the old chlorophyll to disappear and yellow and orange pigments to become visible. The intensity of the colors is connected to temperature, and the drier autumn weather triggers a hormone telling the tree to drop its leaves. Evergreens have a waxy coating and contain a chemical like anti-freeze to survive the winter. By learning about these concepts, students can gain a deeper appreciation for the natural world and develop critical thinking skills. Additionally, understanding the science behind fall leaves can inspire students to explore other scientific topics and engage in self-directed projects.
Have you ever wandered through a forest and wondered about the secrets that lie within? The Hidden Life of Trees by Peter Wohlleben is a fascinating exploration of the communication and community that exists within forests. Wohlleben shares his love for the woods and explains the incredible processes of life, death, and regeneration that take place in the woodland. Through groundbreaking discoveries, he reveals the previously unknown life of trees and their communication abilities. Discover how trees live together with their children, share nutrients, and create an ecosystem that benefits the whole group. Recommended for environmentalists, biologists, ecologists, and anyone interested in the natural world. The Hidden Life of Trees provides a unique perspective on the life and communication of trees, revealing the intricate processes of the forest ecosystem. It offers insights into the importance of community and the impact of solitary life on trees, which can also be applied to human society. This book is relevant to those interested in environmental sustainability and the impact of eco-friendly practices on the health of our planet. It is also a fascinating read for those who simply appreciate the beauty and complexity of the natural world.
Want to know the secret to drought-resistant plants? A group of researchers from Yale, Bates College, University of Maine, Haverford College, and other institutions have discovered that plants with more complex water transport structures are more resistant to droughts, increasing their chances of survival and passing on this trait to their offspring.
Scientists have developed a simple and low-cost method to break down almost a dozen types of "forever chemicals" known as PFAS, which have contaminated virtually every drop of water on the planet and are associated with certain cancers and thyroid diseases. By using a chemical guillotine and common solvents and reagents, they severed the molecular bonds in PFAS, gradually nibbling away at the molecule until it was gone, leaving behind only safe byproducts. This breakthrough could eventually make it easier for water treatment plants to remove PFAS from drinking water.
Have you ever been amazed by the intricate designs found in nature, such as spider webs and butterfly wings? These natural wonders have served as a source of inspiration for some of the most groundbreaking inventions in human history. From airplane wings to bullet trains, the principles of nature are all around us, and today we will explore some of these incredible innovations and the amazing natural phenomena that inspired them. For example, the lotus leaf displays a natural phenomenon called the Lotus Effect. After a rain, water droplets just roll right off the leaf. Upon more intensive research, scientists found out that the lotus leaves' self-cleaning properties are a result of ultra hydrophobicity, inspiring many inventions that repel water, such as self-cleaning windows and waterproof clothing. In addition, gecko feet have inspired researchers to develop new adhesives that could revolutionize the way we build things. The principles of biomimicry, where scientists study the natural world to inspire new technology, have been used to design high-speed trains, such as the kingfisher bird's beak inspiring the train's noise-reducing and efficiency-increasing design. Furthermore, researchers studying the abalone shell and other natural materials have found inspiration to create stronger and more durable materials using nanotechnology. Leading academics such as Janine Benyus, author of Biomimicry: Innovation Inspired by Nature, and Dr. Joanna Aizenberg, a leading researcher in the field of biomimetics who has studied the Lotus Effect extensively, have contributed to the research and development of these innovations. The natural world is full of wonders waiting to be explored. By studying the principles of nature, we can inspire new innovations that could change the world. So go out there and discover the secrets of nature for yourself!
Calcium carbonate may sound like just another chemical compound, but it’s actually the building block for some of the most exquisite and diverse structures found in the ocean, from pearls to shells to coral. Creatures like mollusks use calcium carbonate to carefully construct their shells, controlling their composition at the molecular level to achieve stunning colors and patterns. Learning about the artful ways in which these creatures use calcium carbonate to create their protective structures not only expands our understanding of the natural world but also teaches us about the importance of adaptation and resilience. By exploring this topic further, you can develop a deeper appreciation for the intricacies of the natural world and the ways in which organisms have evolved to survive and thrive in their environments.
Chemical reactions are essential to life and the world around us. From the simple process of combustion to the complex reactions that occur in living organisms, chemical reactions are constantly happening all around us. But have you ever wondered what happens on a molecular level during a chemical reaction? In this write-up, we will investigate the dynamics of chemical reactions and explore the fascinating world of molecules in motion. At the heart of every chemical reaction are the molecules involved. Molecules are constantly in motion, vibrating and colliding with one another. During a chemical reaction, the atoms in these molecules rearrange themselves to form new substances. This rearrangement is driven by the energy released or absorbed during the reaction. Chemical reactions can be classified based on the types of molecules involved and the way in which the atoms rearrange themselves. For example, in an oxidation-reduction reaction, one molecule loses electrons while another gains electrons. In an acid-base reaction, a proton (H+) is transferred from one molecule to another. One of the key factors that influence the dynamics of a chemical reaction is the activation energy. This is the minimum amount of energy required for a reaction to occur. Once the activation energy is overcome, the reaction can proceed spontaneously. The rate at which a reaction proceeds is also affected by other factors such as temperature, concentration, and the presence of a catalyst. Over the years, many leading scientists have made significant contributions to our understanding of chemical reactions. For example, in the early 20th century, Max Bodenstein developed the concept of reaction rates and showed that chemical reactions could be treated quantitatively. Later, Linus Pauling developed the concept of electronegativity, which explains how atoms bond to one another. In conclusion, the dynamics of chemical reactions and the motion of molecules are fundamental to our understanding of the world around us. By exploring this topic further, students can gain a deeper appreciation for the complexity and beauty of the chemical world.
Discover a world of innovation and design inspired by nature's ingenious mechanisms. From the humble cocklebur to the sacred lotus plant, Peter Forbes' book reveals how nature's intricate patterns have given rise to cutting-edge inventions such as Velcro, space solar panels and self-cleaning surfaces. Explore the fascinating science of bio-inspiration and uncover the hidden secrets of the natural world that have inspired architects and engineers alike. Forbes' engaging writing style will inspire you to look at the world around you in a new light and appreciate the beauty and functionality of nature's designs." Recommended for students of biology, engineering, architecture, and environmental studies, as well as anyone interested in the intersection of science and design. This book will appeal to those curious about how the natural world has inspired human innovation and how we can continue to learn from nature to create sustainable solutions. Professionals in fields such as materials science, product design, and biomimicry will find this book a valuable resource for understanding the principles of bio-inspiration. Moreover, this book is relevant to anyone who wants to explore the beauty and complexity of nature's designs and appreciate the wonders of the natural world.
Have you ever imagined walking alongside a giant, hairy elephant with long tusks and a hump of fat on its back? Meet the woolly mammoth, an extinct species that lived during the Ice Ages. As you learn about the woolly mammoth, you will discover fascinating features such as their two-layered fur and impressive size, which was larger than modern elephants. More than just a fun fact, studying extinct animals like the woolly mammoth can help us understand how Earth's climate and environment have changed over time, and how humans have influenced the planet. By exploring these academic concepts through reading, reflection, writing and self-directed projects, you can develop your intellectual curiosity and creativity while also gaining practical skills in research, critical thinking, and communication.
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