In "The Soil Will Save Us," Kristin Ohlson argues that the solution to climate change may lie beneath our feet. Thousands of years of poor farming practices and modern agriculture have stripped the world's soils of up to 80% of their carbon, contributing to atmospheric warming. But by adopting ecological approaches that prioritize the health of soil and its microorganisms, we can turn atmospheric carbon into beneficial soil carbon and potentially reverse global warming. Ohlson introduces readers to the visionaries who are figuring out how to build healthy soil and solve problems like drought, erosion, pollution, and food quality. Recommended for environmentalists, farmers, scientists, and anyone interested in sustainable agriculture and combating climate change. Kristin Ohlson's "The Soil Will Save Us" challenges conventional thinking about farming practices and offers a hopeful solution to the climate crisis. The book has particular relevance to those studying ecology, environmental science, and agriculture, as well as those working in fields related to food and sustainability. It highlights the importance of healthy soil and its role in mitigating the effects of climate change, making it a must-read for anyone interested in creating a more sustainable future.

Did you know that approximately 40% of the global fish catch is discarded as bycatch, unintentionally caught fish that are not the target of the fishing operation? This means that a significant amount of fish, which could be used for food and other purposes, is being wasted. Fortunately, researchers and industry leaders are coming up with innovative solutions to turn bycatch into valuable resources. Bycatch can be transformed into fish meal, used as fertilizer, or even turned into high-end seafood products. One of the leading experts in this field is Dr. Daniel Pauly, a fisheries scientist and professor at the University of British Columbia. Dr. Pauly is known for his work on developing methods to estimate global fish catches, and he has also been a vocal advocate for reducing bycatch and promoting sustainable fishing practices. Another academic making significant contributions in this area is Dr. Karin Limburg, a fisheries biologist and professor at the SUNY College of Environmental Science and Forestry. Dr. Limburg has researched the use of bycatch for fertilizer and has found that it can be a valuable source of nutrients for crops. In addition to these experts, industry leaders such as FishWise, a nonprofit seafood sustainability consultancy, are also working to reduce bycatch and promote sustainable fishing practices. They work with major seafood retailers and distributors to improve the sustainability of the seafood supply chain. By exploring this topic further, you can develop a deeper understanding of the complex issues facing our oceans and contribute to finding innovative solutions for a more sustainable future.

Are you a fan of seafood, but concerned about sustainability? Mock meats have already made their way to the forefront of plant-based cuisine, and now faux seafood is taking center stage. From shrimp to tuna to even sushi, innovative companies are using seaweed, plant protein, and other natural flavors to recreate the taste and texture of seafood without harming the oceans. The Culinary Institute of America has even teamed up with a vegan shrimp startup, New Wave Foods, to perfect the flavor of their shellfish substitute. Whether you're a vegetarian or simply looking to reduce your carbon footprint, these plant-based seafood options are worth a taste test.

Food is a fundamental necessity for all living beings, but the way we produce it has a massive impact on the environment. The growing population and increased demand for food have put significant pressure on traditional agriculture to meet global food needs. Biotechnology has emerged as a promising solution for sustainable food production. Biotechnology involves using living organisms or their products to improve agricultural processes. It has revolutionized food production by providing more efficient, sustainable, and eco-friendly ways to grow and distribute food. Biotech innovations have led to the development of genetically modified crops, which can resist pests, diseases, and environmental stresses, and have higher yields. One leading academic in the field is Dr. Pamela Ronald, a plant geneticist at the University of California, Davis. Dr. Ronald's research focuses on improving crop sustainability and resilience to environmental challenges, such as drought and disease. She has discovered genes that allow rice plants to withstand flooding, a common problem in rice-growing regions. This breakthrough has the potential to improve rice yields and food security for millions of people worldwide. Another notable academic is Dr. Zachary Lippman, a plant biologist at Cold Spring Harbor Laboratory in New York. Dr. Lippman's research focuses on improving crop yield and quality using biotechnology. He has developed a tomato plant that can produce three times more fruit than a traditional tomato plant. His research has the potential to reduce food waste and increase food availability. Biotech's impact on sustainable food production extends beyond crop cultivation. For example, biotech companies are developing new plant-based meat alternatives that taste and look like meat but are more sustainable and eco-friendly. One company leading the way in this field is Impossible Foods, which uses biotechnology to produce plant-based meat substitutes that have the same texture and taste as traditional meat, but with a smaller carbon footprint. In conclusion, biotechnology has the potential to transform the way we produce and consume food sustainably. By exploring this topic further and pursuing self-directed projects, high school students can contribute to the global conversation on sustainable food production and help shape a better future for all.

Alaskan fisherman Dune Lankard has witnessed the devastating impacts of natural and man-made disasters on his industry and homeland, from earthquakes to oil spills. Now, he's turning to regenerative ocean farming to mitigate the effects of climate change and create a new regenerative economy based on conservation, restoration, and mitigation. This burgeoning concept, developed by Canadian commercial fisherman turned ocean farmer Bren Smith, involves growing seaweed and shellfish in small underwater gardens, and is touted as the new farming model of the future. Explore the fascinating intersection of traditional fishing practices and sustainable ocean farming in this thought-provoking article.

The invasion of purple sea urchins has devastated kelp forests along the coasts of California, Japan, Norway, Canada, and Tasmania, leaving behind barren underwater landscapes that can last for decades. However, a Norwegian company called Urchinomics has a plan to restore kelp forests and create a new fishery for overpopulated urchins through "urchin ranching." Urchin ranching could potentially create a local speciality dining market for purple urchin uni, but it will take an aggressive and thorough approach to remove enough urchins to restore kelp forests.

Your favorite chocolate, moisturizer, and tea may contain ingredients from threatened plants, leading to environmental damage and worker exploitation. A recent report highlights 12 such plants, including Brazil nuts and frankincense, and warns of overharvesting, child labor, and violations of worker's rights. As the demand for natural products grows, it's important to consider the sustainability of their ingredients. Learn more about the risks and challenges of sourcing plant derivatives in household products.

Seaweed may be the future of sustainable and nutritious food. As the global population continues to grow and traditional agriculture methods take a toll on the environment, seaweed could be a more efficient and eco-friendly option. Researchers are exploring the potential of seaweed not only as a food source, but also as a tool to combat climate change. Companies like Dutch Weed Burger, AKUA, and Umaro Foods are already developing plant-based alternatives to meat and dairy using seaweed, which is high in nutrients and can be grown without land or fresh water.

Have you ever heard of growing plants without soil? It's possible with hydroponics and aquaponics! These innovative methods of agriculture have gained popularity in recent years for their ability to produce high yields of fresh produce while using less space, water, and pesticides than traditional farming. In this write-up, we'll explore the fascinating world of hydroponics and aquaponics, diving into the concepts, benefits, and contributions from leading academics in the field. Hydroponics is the practice of growing plants in nutrient-rich water instead of soil. This method can be done in a variety of ways, from a simple jar with water and plant roots to complex systems using pumps, pipes, and controlled environments. Aquaponics takes it a step further by combining hydroponics with fish farming. In this closed-loop system, fish waste provides nutrients for plants, while plants naturally filter and clean the water for the fish. Did you know that hydroponics and aquaponics can yield up to 10 times more produce than traditional farming methods? This is because the plants receive precisely the nutrients they need, and water is recycled efficiently. Additionally, these methods can be done year-round, in any climate, and with less land space. It's no wonder that hydroponics and aquaponics are gaining attention from both commercial farmers and hobbyists alike. One leading academic in this field is Dr. Dickson Despommier, a professor at Columbia University. He's written extensively on vertical farming, an innovative form of agriculture that takes hydroponics to new heights by stacking layers of plants vertically. Another notable academic is Dr. Rakocy from the University of the Virgin Islands, who pioneered the development of modern aquaponics in the 1980s. In conclusion, hydroponics and aquaponics offer an innovative and sustainable solution to traditional farming methods. With its ability to produce more fresh produce with less resources, it's no wonder why this field is gaining traction. By exploring this topic further, you can discover new and exciting ways to apply academic concepts to real-world problems.

Transform farmland into thriving habitats for nature while hitting UK's climate and biodiversity targets at half the cost? Yes, it's possible! A new study by leading universities shows incentivizing farmers to spare land for habitats is a cost-effective solution.

Livestock farming is a crucial industry that contributes significantly to the global food system. However, traditional methods of livestock farming can have negative impacts on the environment and public health. In recent years, digital solutions have emerged to address these issues and promote sustainable livestock farming practices. Precision Livestock Farming (PLF) is one of the most promising digital solutions for sustainable livestock farming. PLF uses advanced technologies like sensors, cameras, and data analytics to monitor the health and well-being of livestock, optimize feed management, and reduce environmental impacts. By using these technologies, farmers can reduce waste, improve animal welfare, and increase production efficiency. Another significant digital solution is the use of blockchain technology. This technology can help farmers trace the origins of their products, ensuring that they are produced sustainably and meet ethical standards. This helps promote transparency and accountability in the food system, giving consumers greater confidence in the products they buy. Leading academics in the field of sustainable livestock farming include Dr. Daniel Berckmans, a professor of Biosystems Control at KU Leuven in Belgium, and Dr. Wei Guo, a professor of Precision Livestock Farming at China Agricultural University. Both researchers have made significant contributions to the development and application of digital solutions in livestock farming. Sustainable livestock farming is a critical industry that requires innovative solutions to meet the challenges of the future. By exploring digital solutions, we can build a more sustainable and ethical food system that benefits animals, farmers, and the planet.

Chemical fertilizers are widely used in modern agriculture to boost crop yields. However, these fertilizers are not without risk. In this write-up, we will explore the dangers of chemical fertilizers, including their impact on the environment and human health. We will also examine the alternatives to chemical fertilizers and the role of specific academics in this field. Chemical fertilizers can have a negative impact on the environment, particularly when they are not used in moderation. Excessive use of nitrogen fertilizers can lead to nitrate pollution in waterways, harming aquatic life and posing risks to human health. This pollution can also contribute to algal blooms, which can lead to the formation of dead zones in water bodies. In addition, the production and use of chemical fertilizers can contribute to greenhouse gas emissions, exacerbating climate change. The negative impacts of chemical fertilizers are also beyond human health. Exposure to high levels of fertilizer dust can cause respiratory problems, while exposure to nitrates in drinking water has been linked to an increased risk of certain types of cancer. Pesticides that are often used in conjunction with chemical fertilizers can also pose risks to human health. There are a number of alternatives to chemical fertilizers that can reduce their negative impact. These include organic and natural fertilizers, such as compost and manure, as well as crop rotation and cover crops. In addition, precision agriculture techniques can help farmers apply fertilizers more efficiently and effectively, reducing the risk of pollution. Leading academics in the field of sustainable agriculture have made significant contributions to our understanding of the dangers of chemical fertilizers and the alternatives that exist. For example, Dr. David Montgomery, a geologist at the University of Washington, has written extensively on the impact of industrial agriculture on soil health, and the benefits of regenerative agriculture practices. Similarly, Dr. Rattan Lal, a soil scientist at Ohio State University, has focused on the use of carbon sequestration techniques in agriculture to reduce greenhouse gas emissions. Chemical fertilizers pose a significant risk to the environment and human health, but there are alternatives that can be used to reduce these risks. By exploring the work of leading academics in the field, we can gain a deeper understanding of these issues and work to promote sustainable agriculture practices.

In a world drowning in plastic waste, a new trend of "zero-waste" supermarkets is taking hold. Live Zero, a Hong Kong-based store, is leading the way by doing away with packaging altogether. From bulk bins of chocolate and dried fruit to solid shampoo bars, customers bring their own containers to fill up on just what they need. Although it presents challenges, this movement is gaining momentum, and could pave the way for new eco-friendly solutions, such as compostable bioplastics and reusable packaging systems. Zero-waste shopping may not replace traditional supermarkets, but it offers a promising path forward in the fight against plastic pollution.

Do you know where your food comes from? In 'The Omnivore's Dilemma: A Natural History of Four Meals', Michael Pollan takes you on a journey from the industrial food complex to foraging in the wild, revealing the hidden costs of our modern food systems. As you follow each food chain, you'll learn how our eating choices impact not only our own health but also the health of the environment. Pollan's insightful exploration of our relationship with food will make you question everything you thought you knew about what's on your plate. Recommended for anyone interested in food systems, environmental sustainability, health, and ethics. This book is relevant to students interested in fields such as agriculture, biology, nutrition, environmental studies, and ethics. It is also relevant to anyone who cares about the impact of their food choices on their health and the health of the planet. The book challenges readers to think critically about the industrial food complex and consider alternative ways of producing and consuming food that prioritize sustainability and ethical considerations.

In "Animal, Vegetable, Miracle," Barbara Kingsolver and her family embark on a year-long journey to live off food from their own neighborhood, shunning the industrial-food pipeline. This memoir-journalistic investigation hybrid will take you on a thought-provoking adventure, revealing the true meaning of "you are what you eat." Kingsolver's enthralling narrative will open your eyes to the importance of locally sourced food, sustainability, and self-sufficiency. Recommended for environmentalists, foodies, sustainability advocates, and anyone interested in the impact of food on our health and the planet. This book will also appeal to those studying agriculture, ecology, and environmental science. Kingsolver's memoir will inspire readers to rethink their food choices and consider the benefits of locally sourced produce. Additionally, this book will be relevant to those interested in self-sufficiency and homesteading.

If you love the outdoors, have a passion for science, and want to make a difference in the world, then a career in Agricultural Sciences might be just what you're looking for! Agricultural Sciences is a field that encompasses the study of plants, animals, and the environment, and how they all interact with each other. It's a fascinating area of study that combines biology, chemistry, and engineering to help us better understand the natural world and how we can use it to improve our lives. As an Agricultural Scientist, you could work in a variety of roles, from researching new crop varieties and developing sustainable farming practices, to studying animal behaviour and improving livestock breeding techniques. You might even work in the food industry, helping to develop new products or improve existing ones. Some of the most exciting aspects of this field include the potential to work with cutting-edge technology, such as drones and sensors, to gather data and make informed decisions. You could also have the opportunity to travel the world, working on projects in developing countries and helping to improve food security and sustainability. Typical duties in Agricultural Sciences might include conducting experiments and field trials, analyzing data, writing reports and research papers, and presenting findings to colleagues and stakeholders. You might also work closely with farmers, ranchers, and other agricultural professionals to help them implement new practices and technologies. There are many areas of specialization within Agricultural Sciences, including plant breeding, soil science, animal science, and food science. Other related fields include environmental science, ecology, and biotechnology. To pursue a career in Agricultural Sciences, you'll typically need a Bachelor's degree in a relevant field, such as Agricultural Science, Biology, or Environmental Science. Some popular undergraduate programs and majors include Crop Science, Animal Science, and Food Science. Helpful personal attributes for success in this field include a strong work ethic, attention to detail, good communication skills, and a passion for learning. You should also be comfortable working both independently and as part of a team. Job prospects in Agricultural Sciences are generally good, with a growing demand for professionals who can help address global challenges such as climate change, food security, and sustainable agriculture. Potential employers include government agencies, research institutions, and private companies such as Monsanto, Syngenta, and Cargill. So if you're looking for a rewarding and exciting career that combines science and nature, consider a career in Agricultural Sciences!

In just 70 years, the UK's landscape has undergone drastic changes, with non-native species thriving and native plants dwindling due to modern agriculture and climate change. The Plant Atlas 2020, produced by the Botanical Society of Britain and Ireland, reveals the catastrophic loss of grasslands, heathlands, and other habitats that would shock those brought up in the 1950s. The survey also highlights the impact of climate change on plant life and calls for stronger laws and sustainable land management to protect flora. Sir David Attenborough presents a new BBC documentary, Wild Isles, on the subject.

In today's world, it's easy to take for granted the food we eat and where it comes from. However, understanding the complex supply chain behind the fruits and vegetables we purchase can have significant intellectual and practical benefits. In times of crisis, like during the COVID-19 pandemic, supply chains are stretched thin, and it becomes more important than ever to explore alternative ways of growing food. Enter high-tech urban agriculture, a revolutionary concept that could transform the way we produce and consume food. With vertical farms popping up in cities worldwide, growing crops closer to where they are eaten is becoming a reality. These systems provide numerous benefits, from being healthier and more sustainable to containing no pesticides. By exploring these cutting-edge concepts further, students can gain knowledge about sustainable practices, future technologies, and global supply chains.

Polyculture farming is a sustainable agricultural practice that involves growing multiple crops in the same field at the same time. Unlike monoculture farming, which relies on a single crop, polyculture farming promotes crop diversity, which has numerous ecological benefits. One of the significant advantages of polyculture farming is its ability to enhance climate resilience. Due to climate change, extreme weather events such as floods and droughts have become more frequent, causing significant crop losses. However, by growing multiple crops, polyculture farming minimizes the risk of complete crop failure. Additionally, different crops have different root depths, which enhances soil health and reduces the risk of soil erosion. Furthermore, polyculture farming promotes biodiversity. Different crops attract different insects, birds, and other wildlife, creating a more diverse ecosystem. This, in turn, promotes natural pest control and reduces the need for harmful pesticides. Dr. Miguel Altieri, a professor at the University of California, Berkeley, has been a leading advocate for polyculture farming. He has conducted extensive research on agroecology, which emphasizes the importance of ecological principles in agriculture. Another notable researcher in this field is Dr. Ivette Perfecto, a professor at the University of Michigan. She has studied the role of biodiversity in sustainable agriculture and has found that polyculture farming can increase crop yields while promoting environmental sustainability. Polyculture farming is a promising solution to the challenges posed by climate change and the need for sustainable agriculture. Through crop diversity, it promotes ecological resilience and biodiversity, making it a vital part of our efforts to build a more sustainable future.

Soybeans have been used for centuries in Asian cuisine, but American industrialist Henry Ford took soy to the next level in the 1930s. Soy's versatility and ability to grow easily and cheaply in variable conditions make it a staple in many foods, from mayonnaise to biodegradable plastic. Soy proteins and fats have been used to make spongy foods like tofu and to help make processed foods. Soybeans are also a great source of essential amino acids and "good" fats, which can decrease cholesterol and reduce the risk of heart disease. However, the widespread use of soy has led to deforestation and the displacement of farmers and indigenous communities. Learning about the benefits and challenges of soy can help students become more aware consumers and understand the importance of finding ways to use soy humanely and sustainably.