The book is unique in highlighting the issue of wastewater as one of the important environmental issues. The uniqueness also lies in exploring the concepts of converting waste into resources in the form of bioenergy, biofertilizers through various biological methods. Given the international scenario, the chapters of this book are designed to include both anaerobic and aerobic methods of resource recovery from the industrial wastewater. The book is a step toward design with nature and the concept of green chemistry. Waste menace is one of the most voiced and unsolved problems in the entire world. The whole world is facing the threat of water pollution, soil pollution/ land pollution, odour pollution from the growing waste. Though we find many missions and programs at international, national, and regional level to solve the waste associated issues, this is mostly in context with the solid fraction of the waste. Very little is being done to manage the liquid part of the waste or what we call the wastewater. The conversion of wastewater has the potential to be converted to energy in the form bioenergy, bio-fertilizers, electricity, nutrient recovery, etc. The use of sludge as biofertilizers solves the problem of sludge management on the one hand and production of organic crops on the other. The biological treatment methods like sludge treatment gives the farmers the source of biofertilizers and organic manure for the plants. In the present scenario, energy crisis is also one of the issues that we are facing particularly in context with the thermal power plants which are environmentally highly polluting. Through various techniques like microbial fuel cells or biohydrogen, we get a source of cleaner energy. So, through this book, we try to produce the content and information to give the audience an understanding of the waste water as one of the environmental and health issues and mitigation strategies. The book gives a sufficient understanding of how waste can be turned into a resource.

Covers all aspects related with Metal Organic Frameworks (MOF), including characterization, modification, applications, and associated challenges Illustrates designing and synthetic strategies for MOFs Describes MOFs for gas adsorption, separation and purification, and their role in heterogeneous catalysis Covers of sensing of different types of noxious substances in the aqueous environment Includes concepts of molecular magnetism, tunable magnetic properties and future aspects

Nanomaterials in Bionanotechnology: Fundamentals and Applications offers a comprehensive treatment of nanomaterials in biotechnology from fundamentals to applications, along with their prospects. This book explains the basics of nanomaterial properties, synthesis, biological synthesis, and chemistry and demonstrates how to use nanomaterials to overcome problems in agricultural, environmental, and biomedical applications. Features Covers nanomaterials for environmental analysis and monitoring for heavy metals, chemical toxins, and water pollutant detection Describes nanomaterials-based biosensors and instrumentation and use in disease diagnosis and therapeutics Discusses nanomaterials for food processing and packaging and agricultural waste management Identifies challenges in nanomaterials-based technology and how to solve them This work serves as a reference for industry professionals, advanced students, and researchers working in the discipline of bionanotechnology.

Approx.652 pages

Wood decay is a deterioration of wood by primarily enzymatic activities of microorganisms. For practical purposes, fungi are the only agents of wood decay. Fungi which grow on wood are sometimes called "lignicolous" fungi. But why develop a set of keys limited to fungi utilizing wood as a substrate? After all, being lignicolous does not define a taxonomic category. Lignicolous fungi include ascomycetes and basidiomycetes and a large number of classes and orders within each of these groups. Most of these taxa include both lignicolous and terrestrial species. Rather than taxonomy, the keys focus on the biological activity holding this otherwise disparate group of fungi together: their ability to degrade cellulose and lignin, the major components of wood. Forest trees and valuable landscape trees can be infected and rotted by these fungi. Knowing the species growing on a tree can help the forester determine the likely extent of loss. Different species are associated with different amounts of decay in the tree. Additionally, some species are restricted to sapwood and will not affect the merchantable volume of heartwood. Some fungi can decay sound wood; others decay only decaying wood.

Nanobiotechnology for the Livestock Industry: Animal Health and Nutrition delivers a multidisciplinary reference of nanobiotechnology applications in various sectors, including farming practices, healthcare and breeding practices, market and economic analysis/benefits, biosafety, regulation, and more. The book explores nanobiotechnology's role in livestock handling, including hygiene maintenance and feed/nutrient delivery. The book also examines nanobiotechnology's role in maintaining nutrient quality in food products, and covers healthcare practices utilizing nanobiotechnology, such as maintaining and monitoring livestock health, diagnosis and treatment of disease, monitoring drug delivery, optimizing breeding patterns, and cryopreservation of sperm and eggs.