Are you passionate about the environment and curious about the impact of climate change on our planet? Then a degree in Climate Science could be the perfect fit for you! Climate Science is an exciting and rapidly evolving field that encompasses a range of disciplines, from atmospheric science to ecology and beyond. One of the most appealing aspects of studying Climate Science is the opportunity to make a real difference in the world. As a Climate Scientist, you'll be at the forefront of efforts to understand and mitigate the effects of climate change. You'll study everything from the causes and consequences of global warming to the ways in which we can reduce our carbon footprint and protect the planet for future generations. There are countless fascinating areas of research within the field of Climate Science. For example, you might study the impact of rising sea levels on coastal communities or investigate the ways in which climate change is affecting agriculture and food security around the world. You might also explore the latest innovations in renewable energy technology or examine the role of policy and advocacy in shaping global climate action. At the undergraduate level, students typically take a range of modules that cover the fundamentals of Climate Science, including meteorology, oceanography, and geology. As you progress through your degree, you'll have the opportunity to specialize in areas such as climate modeling, climate policy, or environmental management. And with a degree in Climate Science, you'll be well-equipped to pursue a range of exciting careers in fields such as environmental consulting, renewable energy, or climate policy. Some of the most exciting potential employers for Climate Science graduates include government agencies such as the Environmental Protection Agency or the National Oceanic and Atmospheric Administration, as well as private-sector companies like Tesla and Google. And with the growing urgency of the climate crisis, there's never been a better time to pursue a career in this field. To succeed in Climate Science, you'll need to be curious, analytical, and passionate about making a difference in the world. Strong skills in math and science are also essential, as is a deep interest in the natural world and a commitment to sustainability. So if you're ready to take on one of the most pressing challenges of our time, a degree in Climate Science could be the perfect choice for you!

Are you passionate about protecting the environment and making a positive impact on the world? If so, a career in Environmental Engineering might be the perfect fit for you! Environmental Engineers are responsible for designing and implementing solutions to environmental problems. From developing sustainable energy sources to managing waste disposal, Environmental Engineers work to create a healthier and more sustainable planet. One exciting aspect of this field is the opportunity to work on real-life projects that make a difference. For example, an Environmental Engineer might design a water treatment system to provide clean drinking water to a community in need, or develop a plan to reduce greenhouse gas emissions from a factory. Typical duties of an Environmental Engineer include conducting environmental impact assessments, designing and implementing pollution control systems, and managing hazardous waste disposal. There are also many areas of specialisation within the field, such as air quality management, water resource management, and renewable energy. To become an Environmental Engineer, you will typically need a Bachelor's degree in Environmental Engineering or a related field such as Civil Engineering or Chemical Engineering. Popular undergraduate programs include the Bachelor of Science in Environmental Engineering at the University of California, Berkeley, and the Bachelor of Engineering in Environmental Engineering at the University of New South Wales in Australia. Helpful personal attributes for a career in Environmental Engineering include strong problem-solving skills, attention to detail, and a passion for sustainability. You should also be comfortable working with a variety of stakeholders, including government agencies, private companies, and community groups. Job prospects for Environmental Engineers are strong, with a projected growth rate of 8% from 2019 to 2029. There are many attractive potential employers in both the public and private sectors, including government agencies such as the Environmental Protection Agency in the United States, and private companies such as Tesla and Google. So if you're looking for a career that combines your passion for the environment with your love of problem-solving, consider a career in Environmental Engineering. You could be the next person to make a positive impact on our planet!

Tyres have revolutionized transportation, transforming the way we travel and changing society as we know it. From humble beginnings to modern innovations, the history of tyres is a story of creativity, ingenuity, and progress. The earliest tyres were made of solid rubber, and were prone to punctures and blowouts. John Boyd Dunlop, a Scottish veterinarian, revolutionized tyre design in 1888 by creating the first practical pneumatic tyre. This new design consisted of a rubber tube filled with air, encased in a fabric cover. Since then, tyres have continued to evolve, with advances in materials, tread design, and durability. The invention of the tyre had a profound impact on society. It enabled the development of faster and more efficient modes of transportation, from bicycles to automobiles to airplanes. The ability to transport goods and people quickly and efficiently has transformed economies and societies, making the world smaller and more interconnected. However, the production and disposal of tyres also have environmental impacts. The production of tyres requires significant amounts of energy and raw materials, while the disposal of worn-out tyres creates large amounts of waste. Tyre wear pollution also contributes to air and water pollution, which can have negative impacts on human health and the environment. Several leading academics and innovators have made significant contributions to the development of tyres. Charles Goodyear, an American inventor, developed the process of vulcanization, which made rubber more durable and usable in a wider range of applications. Michelin, a French tyre manufacturer, developed the radial tyre, which greatly improved handling and fuel efficiency. The history of tyres is a fascinating topic that offers insights into the ways in which human ingenuity has transformed the world. By exploring this topic further, students can gain a deeper understanding of the social, economic, and environmental impacts of this important invention.

As demand for materials like copper and lithium skyrockets with the push for clean energy, companies are eyeing the ocean floor for a new source. But what are the potential consequences for marine life and ecosystems? Learn about the growing controversy and the UN's efforts to regulate deep-sea mining in this thought-provoking article.

The world is constantly changing, and as high school students, it is essential to be aware of the problems that need solutions. Vinisha Umashankar, a 14-year-old from India, noticed the pollution caused by charcoal usage in the metal irons of street vendors and decided to take action. She designed an ironing cart powered by solar energy, eliminating the use of charcoal, deforestation, air pollution, and respiratory diseases caused by the traditional method. Learning about solar energy and sustainable solutions like Vinisha's can benefit you not only intellectually but practically as well. By exploring these concepts further, you can contribute to creating a better world for yourself and the generations to come.

Electric vehicles have come a long way since their inception in the late 19th century. While they were once the preferred mode of transportation due to their efficiency and reliability, the high cost of batteries and the discovery of oil reserves led to a decline in their popularity. However, with the growing concern over climate change, electric vehicles are making a comeback. They are now more cost-effective, efficient, and widely available than ever before. Not only do they accelerate faster than gas-powered cars, but they also save drivers money in the long run. With governments around the world focusing on reducing carbon emissions, it's expected that electric vehicles will soon replace gas-powered ones entirely. As a high school student, learning about the history and advancements in electric vehicles can provide valuable insight into the intersection of technology and environmentalism, and inspire you to think about how you can contribute to a sustainable future.

The story of Rudolf Diesel, the man behind the diesel engine, is a fascinating tale of innovation and environmentalism. Diesel's revolutionary compression ignition engine was more eco-friendly and power efficient than alternatives at the time, and it could run on a variety of fuels including coal dust and vegetable oils. Diesel became an evangelist for the use of vegetable oils as fuel, and his invention made him a millionaire by the time he reached his 40s. The benefits of exploring this academic concept are clear: understanding the history of innovation and environmentalism can inspire us to think creatively about how we can make our world a better place. Additionally, learning about the diesel engine can help us think critically about current debates around diesel fuel and its environmental impact. By exploring this academic concept, we can become more informed citizens and better equipped to make decisions that positively impact our world.

Are you interested in learning about innovative ways to combat climate change and food loss? Check out this article from MIT about a new system that uses passive cooling to preserve food crops and supplement conventional air conditioners in buildings, with no need for power and only a small need for water. The system cleverly combines previous standalone cooling designs to produce significantly more cooling overall, enough to help reduce food losses from spoilage in parts of the world that are already suffering from limited food supplies. Read more about this exciting development in the journal Cell Reports Physical Science.

Are you curious about what happens to all the dirty diapers that you throw away? Well, a team of engineers from Japan's University of Kitakyushu has found a way to recycle them into building materials for houses. In a recent article published in Smithsonian Magazine, the researchers explain how they cleaned and shredded dirty diapers to create a small, structurally sound house prototype. This innovative idea could help reduce plastic waste, lower the cost of building materials, and provide more affordable housing options for low- and middle-income communities. Read the full article to learn more about this exciting development in sustainable construction!

Did you know that human activity can cause earthquakes? In fact, they're becoming more common due to drilling, mining, and other subsurface activities. For example, a 5.1 magnitude earthquake in Spain in 2011 was caused by farmers using underground water for irrigation, which caused a shift in the fault line. The oil and gas industry, geothermal power developers, and dam builders have also caused man-made earthquakes. Learning about the science behind earthquakes is not only intellectually fascinating, but it can also help us understand how to avoid making the problem worse. Earthquakes are one of the most catastrophic natural disasters, and there is currently no way to predict when they will strike. As students, we can take an active role in learning about the impact of human activity on the environment and how we can make a positive difference.

The US power grid is the world's largest machine, containing more than 7,300 electricity-generating plants, linked by some 11 million kilometers of powerlines, transformers, and substations. Power grid operators maintain a delicate balance between energy supply and demand, ensuring that their components work in unison and maintain a constant frequency throughout the grid. Power grids contain a mix of carbon-free and carbon-emitting energy sources, and researchers are experimenting with unique storage solutions to make full use of renewable energy sources. By shifting energy use to the times when there's clean electricity to spare, load flexibility can help flatten the peaks in demand, reducing the need for non-renewables. Smart devices like air conditioners, water heaters, and electric vehicle chargers can be implemented to decrease emissions by around 20%. Learning about power grids and renewable energy sources can help students understand the importance of balancing energy supply and demand and inspire them to explore ways to reduce their carbon footprint.

Experience Africa from a whole new perspective with Edward Burtynsky's latest collection of photographs, African Studies. From the geometric patterns of agriculture to the devastating impact of corporate greed, Burtynsky's aerial images capture the intricate relationship between humans and the planet. Discover the beauty and horror of Africa's vast resources, extracted with both modern technology and centuries-old techniques. Explore the impact of China's shifting economy on the African continent, and ponder the abstract beauty of Namibia's Tsaus Mountains. The African continent is a final frontier worth exploring.

In "Storms of My Grandchildren," Dr. James Hansen, the preeminent climate scientist, delivers a powerful and urgent message about the looming threat of global warming. With a stark warning that the planet is hurtling towards a climatic point of no return, Hansen calls for immediate and decisive action to phase out coal and achieve a goal of 350 parts per million of carbon dioxide in the atmosphere. This book is a must-read for anyone concerned about the future of our planet and the fate of future generations. Recommended for students of environmental science, policy makers, and anyone interested in the urgent issue of climate change, "Storms of My Grandchildren" provides a comprehensive and compelling overview of the science behind global warming and the political obstacles to addressing it. The book is an important resource for those seeking to understand the dire consequences of inaction, and the urgent need for a groundswell of public support to create a tipping point for change. Hansen's message is clear: we must act now to save our planet and our grandchildren from a catastrophic fate.

The UN's Decade on Ecosystem Restoration calls for urgent action to restore freshwater ecosystems. A recent study of Australian stream management highlights the need for collaborative, participatory, and adaptive nature-based solutions. Discover how building communities of practice, implementing nature-based solutions, and allocating more resources for adaptive management can help achieve global goals for ecosystem restoration.

Climate change anxiety is a relatively new term, but the fear of the future and the trauma it may bring is not. We are facing an existential fear about our survival, and it is important to understand our impact as human beings on the planet. It is normal to feel anxious about the effects of climate change, but this anxiety can also be a way of digesting the information. As students, it is essential to explore this topic and understand the key concepts of climate change, its impact on our world, and the part we can play in mending the part of the world that is within our reach. Learning about this topic not only benefits us intellectually but also practically as it helps us to make informed decisions about our future and the world we want to live in. Let's embrace the challenge and become part of the solution.

Are you fascinated by the Earth's natural wonders and the forces that shape our planet? Do you enjoy problem-solving and critical thinking? If so, then Geological Engineering might be the perfect field of study for you! Geological Engineering is a branch of engineering that focuses on the study of the Earth's materials, structures, and processes. This interdisciplinary field combines elements of geology, engineering, and mathematics to solve complex problems related to the Earth's resources, natural hazards, and environmental sustainability. One of the most exciting aspects of Geological Engineering is its real-world applications. From designing safe and efficient mines to mitigating the impact of natural disasters, Geological Engineers play a crucial role in shaping our world. For example, Geological Engineers are involved in the construction of tunnels and dams, the exploration and extraction of oil and gas reserves, and the development of renewable energy sources such as geothermal and hydroelectric power. Geological Engineering is also a field of constant innovation and discovery. Recent research has focused on developing new methods for detecting and monitoring earthquakes, predicting volcanic eruptions, and understanding the long-term effects of climate change on the Earth's geology. Some of the most well-known academic figures in this field include Charles Darwin, who studied geology during his voyage on the HMS Beagle, and Marie Tharp, who created the first comprehensive map of the ocean floor. At the undergraduate level, students in Geological Engineering typically take courses in geology, physics, chemistry, and mathematics, as well as specialized courses in topics such as mineralogy, petrology, and structural geology. Students may also have the opportunity to participate in fieldwork and research projects, gaining hands-on experience in the field. After graduation, there are a wide range of potential career paths for Geological Engineers. Some may choose to work in the mining industry, designing and managing mining operations around the world. Others may work in environmental consulting, helping to assess the impact of human activities on the Earth's natural systems. Still others may work in government agencies, such as the United States Geological Survey or the National Oceanic and Atmospheric Administration, where they can contribute to important research and policy decisions. To succeed in Geological Engineering, students should have a strong foundation in mathematics and science, as well as excellent critical thinking and problem-solving skills. A passion for the Earth's natural systems and a desire to make a positive impact on the world are also important qualities for success in this field. So if you're ready to explore the fascinating world of Geological Engineering, start researching universities and programs today! With a degree in this field, you'll be well-prepared for a rewarding and impactful career in a variety of industries around the world.

Imperial researchers have found that integrating solar and battery power in refugee camps can drastically reduce fuel expenditure and emissions while also boosting the local economy. The system, funded in part by a grant from the UKRI Global Challenges and Research Fund, could provide reliable access to electricity for more people. Find out how this innovative solution can improve the lives of displaced people.

Fracking is a technology that extracts natural gas from deep underground. It involves drilling a well and pumping a high-pressure mixture of water and chemicals into the rock to release the gas. Fracking has been a source of controversy due to its impact on the environment, including the potential contamination of drinking water and the release of methane, a potent greenhouse gas. However, natural gas is a cleaner-burning fuel than coal, and fracking has the potential to power us for decades to come. As students, it's important to understand the science and technology behind fracking, as well as the economic and environmental implications. Learning about fracking can help us make informed decisions about our energy use and inspire us to explore alternative, renewable energy sources.

The world's shift towards electric vehicles to reduce greenhouse gas emissions will require a huge demand for critical metals like lithium, nickel, cobalt, manganese, and platinum. This demand will have economic and supply-chain consequences, according to new research from Cornell University. Discover how countries can manage this demand and promote a circular economy for critical metals.

Scientists at A\*STAR's IMRE have successfully upcycled PET plastic waste into polymer electrolytes, which are key components for safer LiBs. This paves the way for a future powered by more sustainable energy, creating a circular economy while combating the mounting plastic waste issue. The team aims to advance the technology for upcycling waste plastics on a larger scale to create components for eco-friendly batteries.