Have you ever wondered about the rocks and minerals that make up the earth's crust, or how mountains are formed? If so, a career in geology might be the perfect fit for you! Geology is the study of the Earth, its processes, and its materials. Geologists explore, analyze, and interpret the Earth's physical and chemical properties, from its deep interior to its surface, including the oceans and the atmosphere. A geologist's work can take them to some of the most exciting and remote places on the planet, such as volcanic islands, deserts, and mountain ranges. They study the Earth's natural resources and hazards, help locate and extract valuable minerals and energy resources, and investigate the effects of human activities on the environment. Geologists have many opportunities for specialization, including mineralogy, volcanology, paleontology, geophysics, hydrogeology, and environmental geology, to name a few. They can work in a wide range of industries and organizations, such as mining, oil and gas exploration, environmental consulting, government agencies, academia, and research institutions. To become a geologist, you will typically need at least a bachelor's degree in geology or a related field, such as earth science, geophysics, or environmental science. Some popular undergraduate programs in geology include those offered by the University of California, Berkeley, the University of Colorado Boulder, and the University of Michigan. Helpful personal attributes for success in this field include a strong curiosity about the natural world, excellent analytical and problem-solving skills, attention to detail, and the ability to work well as part of a team. The job prospects for geologists are good, with a projected annual job growth rate of 5% between 2020 and 2030, according to the US Bureau of Labor Statistics. Geologists can find employment in a wide range of public and private sector organizations, including the US Geological Survey, ExxonMobil, the National Park Service, the United Nations, and many more.

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.

Medieval texts, ice core, and tree ring data reveal how volcanic eruptions triggered the Little Ice Age. Researchers from the University of Cambridge and the University of Geneva examined hundreds of annals and chronicles from across Europe and the Middle East, in search of references to total lunar eclipses and their coloration. They found that the darkest lunar eclipses all occurred within a year or so of major volcanic eruptions, leading to cooling and other climate anomalies. Find out how the monks' records of the brightness and colour of the eclipsed moon helped narrow down when the eruptions must have happened.

The Sun's magnetic fields may seem distant and unimportant to our daily lives, but they actually have a huge impact on Earth. Understanding the science behind solar flares and coronal mass ejections can not only satisfy your curiosity about the world around you, but also help you prepare for potential disruptions to power and communication. Even better, studying these concepts can lead to the awe-inspiring experience of witnessing the stunning auroras, a natural phenomenon caused by the interaction of charged particles with Earth's magnetic field. Don't miss out on the chance to explore these fascinating topics and discover the wonders of our universe.

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

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.

New research shows that the cost of annual flooding in the UK could increase by up to 23% over the next century due to climate change, unless all international pledges to reduce carbon emissions are met. The study, led by the University of Bristol and Fathom, highlights the need for urgent action to mitigate the impact of climate change on the risk of flooding across the UK. The research also identifies the areas of the UK where risks will increase the most, including densely populated cities such as London, Cardiff, Manchester, Glasgow, and Edinburgh.

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

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.

Climate change has led to a rise in severe weather, making storm chasing an addictive pursuit for some. But as the popularity of storm tourism grows, so do the risks. Explore the allure and dangers of chasing nature's raw power, from novice smartphone-wielding enthusiasts to experienced meteorologists, and the impact of social media and the pandemic on the industry. Discover why some experts believe that storm chasing is better left to scientists and the potential hazards of "chaser convergences" and inexperienced drivers.

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

The Netherlands is a country that has a long history of managing water. With almost a quarter of its territory below sea level, the region is prone to flooding. However, the Dutch government has taken measures to protect the entire southwestern region. The Delta Works project is the most sophisticated flood prevention project in the world, and it has reduced the annual odds of flooding to about 1 in 10,000. The project includes various infrastructure projects, such as damming the region's flood-prone estuaries and building the Maeslantkering, which is one of the planet's largest mobile structures. Additionally, the "Room for the River" plan has relocated farms and dikes away from the shore, creating reservoirs and habitats for local wildlife. Rotterdam, a thriving city almost entirely below sea level, embodies the Netherlands' multi-pronged approach to water management. By learning about the Dutch government's innovative solutions to natural disasters, students can gain a deeper understanding of how to create sustainable and resilient communities.

Are you curious about the possibility of asteroids hitting Earth in the next 1,000 years? Well, according to a new study published in The Astronomical Journal and reported by MIT Technology Review, there's good news - none of them are expected to hit us! The study, led by Oscar Fuentes-Muñoz from the University of Colorado, Boulder, used a new method to model when asteroids are expected to come near Earth in their orbit and pushed those estimates up to 1,000 years into the future. Read on to discover more about the study's findings and what this means for our planet's future.

The Leaning Tower of Pisa, one of Italy's most iconic structures, has been saved from a date with gravity through decades of interventions. The latest survey shows the tower's health to be much better than forecasted, having crept upright by 4 centimeters in 21 years since stabilisation works were done.

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

Glass is a material that we use every day, but have you ever wondered how it works? Glass is made from silicon dioxide, which is heated until it becomes a flowing liquid. As it cools, the molecules lose energy and become an amorphous solid, allowing light to pass through without being scattered. The subatomic level of glass is what makes it transparent, as the electrons in glass are spaced far enough apart that visible light can't provide enough energy for them to jump between them. This unique property has made glass an essential material for many uses, from windows to lenses. Understanding the science behind glass can help you appreciate the importance of this material in modern civilization.

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.

Wildfires can have a lasting impact on the ozone layer, a new MIT study shows. Smoke particles from the Australian "Black Summer" megafire triggered a chemical reaction that depleted ozone by 3-5% at mid-latitudes in the southern hemisphere, with effects reaching as far as Antarctica. The study highlights the need to consider the impact of wildfires on ozone recovery efforts and suggests that as long as ozone-depleting chemicals persist in the atmosphere, large fires could spark a reaction that temporarily depletes ozone.

Luke Howard's classification of clouds in the early 1800s revolutionized meteorology and changed humanity's understanding of the skies. Howard's simple insight based on years of observation was that clouds have few basic forms, and he introduced a series of intermediate and compound types to accommodate their essential instability. Howard's classification had an immediate international impact, and clouds became easier to understand as visible signs of otherwise invisible atmospheric processes. Understanding clouds is important in comprehending weather and climate patterns. Howard's classification also had a significant impact on art, with painters like John Constable painting clouds in the open air. Learning about clouds and meteorology can be intellectually stimulating and practically useful in comprehending weather patterns and climate change.

Have you ever wondered what it would be like to predict the weather? To be the one who knows when to pack an umbrella or when to wear sunscreen? If so, a career in meteorology might be perfect for you! Meteorology is the study of the atmosphere and the weather that occurs within it. This field is fascinating and ever-changing, with new discoveries and advancements being made all the time. Meteorologists use science and technology to analyze data and make predictions about weather patterns, climate change, and severe weather events. As a meteorologist, you'll have the opportunity to work in a variety of different areas. Some meteorologists specialize in forecasting weather for television or radio stations, while others work for government agencies, such as the National Weather Service. You could also work for private companies that require weather predictions, such as airlines or energy companies. To become a meteorologist, you'll typically need a bachelor's degree in meteorology, atmospheric science, or a related field. Popular undergraduate programs include Atmospheric Sciences, Environmental Science, and Physics. It's also important to have a strong background in math and computer science. Helpful personal attributes for a career in meteorology include strong analytical skills, attention to detail, and the ability to work well under pressure. You'll need to be able to communicate complex information in a clear and concise manner, as well as work as part of a team. Job prospects for meteorologists are strong, with opportunities available in both the public and private sectors around the world. Notable employers include the National Oceanic and Atmospheric Administration (NOAA), the European Centre for Medium-Range Weather Forecasts (ECMWF), and the Australian Bureau of Meteorology. In conclusion, a career in meteorology is exciting, challenging, and rewarding. With a passion for science and a desire to make a difference, you could be the next meteorologist to predict the next big weather event. So, if you're interested in the weather and want to make a difference in the world, consider a career in meteorology!