Fungi are more than just pizza toppings or irritants like athlete's foot. They are a distinct life-form that plays a vital role in the health of our planet. Fungi can absorb oil spills, control insects' brains, and produce life-saving medicines like penicillin. They are also eco-warriors, essential to healthy soil and trapping CO2, potentially solving global warming on their own. Fungi are neither plant nor animal, but are genetically closer to animals than plants. They form dense fungal networks called mycelium, which plants use to communicate with each other. Fungi can also employ other organisms, like leaf-cutter ants, to do their work for them. Fungi are fascinating and adaptable, and there is still much we have yet to learn about them. By exploring the world of fungi, you can become a real fun-guy at parties and gain a deeper understanding of the world around you.

Climate change is putting numerous European seabirds at risk. A new conservation guide, led by ZSL and University of Cambridge, offers hope for the future of these important marine birds by assessing their specific needs and actions needed for preservation. Don't let iconic species like the Atlantic puffin disappear from our shores!

Tardigrades have even been featured in popular culture, including an episode of Star Trek: Discovery, where they were used as a propulsion system for a spaceship. But while tardigrades may seem like science fiction, they are very much a real and fascinating part of the natural world. These tiny, water-dwelling creatures, also known as water bears or moss piglets, have been around for over half a billion years and have evolved some truly remarkable survival strategies. Tardigrades can survive in extreme environments that would kill most other organisms, including temperatures ranging from -272°C to 151°C, pressures six times greater than those at the bottom of the ocean, and even the vacuum of space. They can also survive dehydration, radiation, and exposure to toxins. Tardigrades achieve this impressive feat through a combination of strategies, including the ability to enter a state of suspended animation called cryptobiosis, which allows them to survive without water for years. One of the key factors that enable tardigrades to survive in such extreme conditions is their ability to repair their DNA. Tardigrades have a unique protein called Dsup, which protects their DNA from damage caused by radiation. This protein has even been shown to protect human cells from radiation damage. Dr. Thomas Boothby, a leading tardigrade researcher at the University of Wyoming, has discovered that tardigrades can also produce large amounts of unique proteins called tardigrade-specific intrinsically disordered proteins (TDPs) in response to desiccation. These proteins help protect the tardigrades' cells from damage and prevent them from drying out. Tardigrades are fascinating not just for their survival abilities, but also for their unique biology. They have a complex digestive system, a unique nervous system, and a fascinating reproductive system that involves the transfer of genetic material between individuals. By exploring the science behind these tiny creatures, we can gain a deeper understanding of the natural world and the amazing ways that living organisms can survive and thrive in even the most extreme conditions.

Stanford-led research finds that the world's largest animals, rorqual whales, owe their size to feeding on tiny creatures in the sea. However, their survival requires a minimum body size, which could put them at risk of extinction due to rapid environmental change. By examining the smallest living species in this group, the authors found that individuals need to grow to at least 4.5 meters to eat enough food to survive. The study sheds light on how climate change might affect krill populations and put certain whale species at risk of extinction.

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.

Maria Sibylla Merian was a naturalist and illustrator who defied convention and made significant contributions to the study of entomology, the study of insects. She was one of the first to describe the metamorphosis of insects in detail and portrayed insects surrounded by the plants they relied on, revealing their relationship to the wider ecosystem. Merian's groundbreaking work, 'The Metamorphosis of the Insects of Suriname', published in 1705, documented many species in Suriname's jungle, and its stunning illustrations depicted stages of development of Suriname's veracious caterpillars and vibrant butterflies. Merian's legacy has endured, and her work on the biodiversity of Suriname is still valued by scientists and could show us how some species may adapt to climate change. Learning about Merian's work can inspire students to explore and appreciate the natural world, understand the importance of biodiversity, and encourage them to pursue their passions despite challenges and societal expectations.

Did you know that whales have their own dialects and build communities just like humans do? By studying whale culture, we can learn a lot about ourselves and about our communities. Whales pass down information through their songs, just as humans share information through stories. Interestingly, whales can even remix their songs when they hear a new hit from a different group of whales. But it's not all serious learning - whales also know how to have fun and enjoy life. By exploring academic topics like whale culture, you can expand your knowledge and gain a deeper understanding of the world around you. Plus, it's just plain interesting! So why not dive in and explore new academic topics that inspire you? You never know what you might discover.

For over a century, dolphins and fishers in Laguna, Brazil have cooperated to catch fish. A new study reveals the mechanics of their partnership, showing how they synchronize their behavior to catch more fish. But this unique fishing practice is facing extinction due to declining fish populations and waning interest from future generations. The study highlights the rarity of interspecies cooperation and the benefits it brings to both humans and wildlife.

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.

The ocean is much more than just a beautiful and mysterious body of water that covers over 70% of our planet. It plays a critical role in regulating the Earth's climate and weather patterns, making it an essential aspect of the global ecosystem. In recent years, the impact of human activities, such as increased greenhouse gas emissions and plastic pollution, has had a profound effect on the ocean and its life. Understanding the relationship between the ocean and climate change is crucial to preserving our planet for future generations. One of the most significant ways in which the ocean affects climate change is through its ability to store and release heat. The ocean acts as a "heat sink," absorbing over 90% of the excess heat caused by climate change, helping to regulate the planet's temperature. This process also affects the ocean's currents, which play a crucial role in the global climate system by transporting heat and nutrients around the world. Another critical aspect of the ocean's role in climate change is its ability to absorb carbon dioxide from the atmosphere. The ocean is a natural carbon sink, but as the levels of carbon dioxide in the atmosphere increase, the ocean becomes more acidic, which can have severe consequences for marine life. This process, known as ocean acidification, is a significant concern for scientists and policymakers because it can disrupt the delicate balance of the ocean's ecosystem and cause harm to species that rely on a stable environment to survive. Leading academics in the field, such as Dr. Sylvia Earle and Dr. Jane Lubchenco, have made significant contributions to our understanding of the ocean's role in climate change. Through their research and advocacy, they have helped to raise awareness of the importance of the ocean and its life and the need to protect it for future generations. The ocean is an integral part of our planet's ecosystem, and understanding its role in climate change is essential for preserving our planet and its life for future generations. Get inspired, get informed, and dive into the deep blue!

Pesticides not targeted at flowers may pose a hidden threat to pollinators, according to new research from Trinity and DCU. The study, the first of its kind in Ireland, found residues of several pesticides in the nectar and pollen of both crop and wild plants, with some chemicals lingering for years after application. The findings have implications for the health of bees and other pollinators, as well as for ecosystem function, crop production, and human health.

Are fast-lived species taking over the world? Recent research published in Global Change Biology found that fast-lived animals are increasing in numbers while slow-lived animals are in decline, especially in areas of rapid cropland or bare soil expansion. The study raises important questions about how human actions are rewiring natural ecosystems and the far-reaching effects on the natural world.

Citizen scientists in Denmark have discovered the oldest scientifically-confirmed European hedgehog, living for 16 years, 7 years longer than the previous record holder. However, the average age of hedgehogs was only around two years, with many dying before their first birthday due to road accidents. Interestingly, male hedgehogs lived longer than females, despite being more likely to be killed in traffic. The research also investigated the impact of inbreeding on hedgehog lifespan, with surprising results. Discover the secrets of hedgehog longevity and conservation efforts in this fascinating study.

Pollinators, such as bees and butterflies, are essential to our planet's biodiversity. They facilitate the reproduction of flowering plants, which in turn support other wildlife and contribute to the overall health of ecosystems. Sadly, pollinators face numerous threats, including habitat loss, pesticides, and climate change. In this write-up, we'll explore the vital role of pollinators in biodiversity conservation, as well as the challenges they face. First, let's define biodiversity. It refers to the variety of life on Earth, including different species, ecosystems, and genetic diversity within species. Pollinators play a crucial role in maintaining this diversity by helping plants reproduce. Over 75% of the world's food crops depend on pollinators, and they also support the growth of wildflowers and other plants that provide habitat for other animals. But pollinators are in trouble. According to the Intergovernmental Science-Policy Platform on Biodiversity and Ecosystem Services (IPBES), over 16% of vertebrate pollinators, such as birds and bats, are threatened with extinction. In addition, around 40% of invertebrate pollinator species, such as bees and butterflies, are facing the same fate. One leading academic in this field is Dr. Dave Goulson, a professor of biology at the University of Sussex. He has conducted extensive research on the importance of pollinators and the threats they face. In his book, "The Garden Jungle," he emphasizes the role of urban gardens in supporting pollinators and other wildlife. Another academic, Dr. Rachael Winfree from Rutgers University, has studied the impact of habitat fragmentation on pollinator communities. Her research shows that smaller patches of habitat can still support pollinators, but it's crucial to have a diversity of plants and habitats available. So, what can we do to help pollinators? There are many actions we can take, from planting pollinator-friendly gardens to reducing pesticide use. We can also support organizations that work to protect pollinators, such as the Xerces Society and the Pollinator Partnership. In conclusion, pollinators play a vital role in maintaining biodiversity, but they face numerous threats. By learning more about pollinators and taking action to protect them, we can help to ensure a healthy and diverse planet for future generations.

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.

Plants have been evolving for millions of years and have developed incredible adaptations to survive in their environments. One of the most impressive adaptations is drought resistance. In this write-up, we will explore the fascinating world of plant evolution and the incredible ways that plants have adapted to survive in dry environments. Did you know that there are plants that can survive without water for years? The cactus is one such plant that has developed unique adaptations to survive in the harsh desert environment. Its thick stems store water, and its shallow roots can quickly absorb moisture when it rains. The cactus also has small leaves that reduce water loss through transpiration and spines that provide shade to the stem, reducing water loss even further. Another interesting example of drought resistance in plants is the succulent. Succulents store water in their leaves, which become plump when water is available and shrink when water is scarce. They also have shallow roots that spread widely to quickly absorb moisture when it rains. Leading academics in the field of plant evolution and drought resistance have made significant contributions to our understanding of these adaptations. For example, Dr. Christine A. Beveridge has studied the molecular mechanisms behind drought resistance in plants and have identified genes that play a crucial role in this process. Her work has led to the development of drought-resistant crops, which have the potential to improve food security in dry regions. In conclusion, the world of plant evolution and drought resistance is full of fascinating facts, stories, and examples. By exploring this topic independently, students can deepen their understanding of the amazing adaptations that plants have developed over millions of years to survive in their environments.

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.

A team of undergraduate students from Colgate University developed SealNet, a seal facial recognition system that uses deep learning and a convolutional neural network to identify harbor seals. SealNet could be a useful, noninvasive tool for researchers to shed more light on seal behavior, including site fidelity and movements. The software shows promise and could be paired with another photo identification method to identify seals by distinctive markings on their pelage. In the future, an app based on SealNet could allow citizen scientists to contribute to logging seal faces.

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 wondered why some animals are bigger than others? Or why some animals live longer or reproduce faster than others? These differences are due to an animal's life-history traits, which can have a significant impact on its chances of survival and reproductive success in different environments. Body size, for example, can affect an animal's ability to find food, avoid predators, and regulate its body temperature. Larger animals may have an advantage in colder environments, where they can retain heat more efficiently, while smaller animals may have an advantage in warmer environments, where they can cool down more easily. In terms of reproduction, larger animals may have more mating opportunities, while smaller animals may have a higher reproductive rate and produce more offspring. Lifespan is another important life-history trait. Some animals, like turtles and whales, can live for many decades, while others, like insects and rodents, have much shorter lifespans. Long-lived animals may have a better chance of surviving through periods of environmental change or fluctuation, while short-lived animals may be able to reproduce more quickly and take advantage of favorable conditions. Reproductive rate is a third key life-history trait. Some animals, like rabbits and mice, can have many offspring in a short period of time, while others, like elephants and humans, have fewer offspring over longer periods of time. High reproductive rates can help animals respond quickly to environmental changes or take advantage of favorable conditions, while low reproductive rates can lead to more parental investment in each offspring and a better chance of survival. So, how do these life-history traits affect animal survival and reproductive success in different environments? To answer this question, scientists study a variety of different animal species and environments, using techniques like field observations, experiments, and modeling. They also use tools like life tables, which show how an animal's survival and reproductive rates change over time, and population models, which predict how a population will change over time based on different factors. Leading scientists in this field include Susan M. C. Clegg, a researcher at the University of Exeter, who studies how life-history traits affect bird populations, and Steven C. Stearns, a professor at Yale University, who has written extensively on life-history theory and evolution. In conclusion, life-history traits play a crucial role in determining an animal's chances of survival and reproductive success. By exploring the fascinating world of life-history traits, students can gain a deeper understanding of how evolution works and how organisms adapt to their environments.