Fate of Biological Contaminants During Recycling of Organic Wastes covers the fate of viruses, HPBs, and ARGs in organic wastes, and their eliminating methods, including composting, vermicomposting and anaerobic digestion. In addition, this work describes the environmental risks associated with the application of excess sludge, livestock and other bio-wastes in soils Fate of Biological Contaminants During Recycling of Organic Wastes will benefit environmental and soil scientists engaged in the latest research regarding risk assessment and remediation techniques in wastewater, and solid wastes, and agricultural wastes. - Covers the fate of viruses, HPBs, and ARGs in wastes as well as their environmental risk to the ecosystem - Includes applications of earthworm remediation techniques, composting, and anaerobic digestion for organic wastes - Introduce the key relationship between viruses, HPBs, ARGs and the microbial community during biological treatment of excess sludge and livestock manure
Occurrence and Behavior of Emerging Contaminants in Organic Wastes and Their Control Strategies provides updated information on the occurrence, monitoring, and behavior of emerging contaminants discharged into the environment from different anthropogenic activities as well as organic wastes management practices, which can be beneficial in classifying and broadly addressing the assessment, treatment, disposal, and management of organic wastes. This book will cover the occurrences of nanoparticles, microplastics, antibiotic resistance genes, disinfection by-products, medical waste, pharmaceutical and personal care products, and other emerging contaminants discharged in different types of organic wastes. Researchers, scientists, graduate, and postgraduate students will find this book to be a timely contribution that will be useful in identifying and comprehensively addressing occurrence and behavior of emerging contaminants in organic wastes. - Covers a broad range of information on different emerging contaminants presented in different types of organic wastes - Deals with insights, behaviors, monitoring, and pathways of emerging contaminants in the classification, transport, treatment, and disposal of organic wastes - Illustrates the environmental risks of emerging contaminants in final waste products of organic wastes - Highlights feasible control strategies for emerging contaminants during the whole process of organic waste management
Earthworm Technology in Organic Waste Management: Recent Trends and Advances is a suitable contribution to the Waste and The Environment: Underlying Burdens And Management Strategies series that will be helpful in classifying and broadly addressing assessments, mitigation strategies, and the management of organic wastes using earthworms. In addition, the book provides a summary of the latest findings on emerging pollution-related issues, their sustainable management, and future perspectives. The book covers recent trends and developments in organic waste management, including the use of earthworms in municipal and industrial waste management, the role of earthworms in vermifiltration/vermiwash, and of vermicompost in crops. Finally, the book covers the potential of earthworms in the remediation of emerging contaminants. This includes antibiotic resistance genes, heavy metals, pesticides, microplastics, and other emerging pollutants that are not covered in-depth in previously published titles. Covers a broad range of information on different aspects of organic waste treatment by earthworm technology Illustrates how earthworms can be used in modeling, assessment and management of environmental issues caused by geogenic, industrial and emerging pollutants Highlights the reuse and recycling of industrial and municipal organic waste and recovery of value-added resources from organic waste
Handbook on Organic Waste for Biological Treatment, Liquid Manure into a Solid, Tomato Waste Water Treatment, Oxalic Acid from Jute Stick, Cotton Processing Waste, Fish Waste, Agro-Industrial Wastes, Bioconversion of Pretreated Wheat Straw and Sunflower Stalks to Ethanol, Agricultural Waste Treatment, Waste of Dehydrated Onion, Beef-Cattle Manure Slurry, Meat Meal and Algae for Calves, Wastes from Large Piggeries, Pig Waste, Oxytetracycline, Methane from Cattle Waste (Also Known as The Complete Book on Biological Waste Treatment and their Utilization) Biological Treatment is the recycling of humus, nutrients and/or energy from biological waste by means of aerobic (composting) or anaerobic (digesting) processing. Biological treatment is an important and integral part of any wastewater treatment plant that treats wastewater from either municipality or industry having soluble organic impurities or a mix of the two types of wastewater sources. Biological wastewater treatment is an important and integral step of wastewater treatment system and it treats wastewater coming from either residential buildings or industries etc. It is often called as Secondary Treatment process which is used to remove any contaminants that left over after primary treatment. Organic waste is material that is biodegradable and comes from either a plant or animal. Organic waste is usually broken down by other organisms over time and may also be referred to as wet waste. Most of the time, it's made up of vegetable and fruit debris, paper, bones and human waste which quickly disintegrate. Wastewater treatment is a process used to convert wastewater, which is water no longer needed or suitable for its most recent use, into an effluent that can be either returned to the water cycle with minimal environmental issues or reused. Expenditure on water and wastewater infrastructure in India is set to increase by 83% over the next five years, hitting an annual run rate of $16 billion by 2020. The utility market is set to top $14 billion within five years, while annual spending in the industrial sector will approach $2 billion. Spending on water supply will grow from $5.56 billion to $9.4 billion over the next five years. It will be a standard reference book for professionals, entrepreneurs, those studying and researching in this important area. TAGS Biological Treatment, Organic-Waste Treatment, Biological Treatment of Organic Waste, Biological Wastewater Treatment, Biological Treatment Plant or Organic Waste, Organic Solid Waste Biological Treatment, Biological Treatment Plant, Microorganisms in Organic Waste Disposal, Biological Treatment of Waste, Process for Biological Treatment of Organic Waste, Biological Treatment Process, Organic Waste Treatment, Organic Waste Recycling, Organic Waste Forms and Treatment Strategies, Biological Waste Treatment and Utilization, Transformation of Liquid Manure into Solid, Tomato Waste Water Treatment, Treatment of Wastewater from Peeled Tomato, Tomato Cleaning and Water Recycle, Preparation of Oxalic Acid from Jute Stick, Oxalic Acid Manufacture, Oxalic Acid from Jute Stick, Digestion of Cotton Processing Waste, Properties of Sorghum Stalk, Physical and Mechanical Properties of Sorghum Stalk, Biological Fermentation of Fish Waste, Fermentation of Fish Waste, Fermented Fish Waste, Fish Waste in Fermentation, Agro-industrial Wastes, Agro-industrial wastes utilization, Recycling of Agro-Industrial Wastes, Modelling of Agricultural Waste Treatments, Utilization of Waste of Dehydrated Onion, Utilization of Waste Products of Dehydrated Onion Industry, Palm Oil Mill Effluent Disposal on Land, Palm Oil Mill Effluent (POME), Palm Oil Mill Effluent (POME) Treatment, Waste Management in Palm Oil Mill, Management and Treatment of Wastes from Large Piggeries, treatment of wastes from piggeries, Treatment of Piggery Wastes, Management of Wastes from Pig, Piggery Waste Management, Tower Digestion of Pig Waste, Nutritive Value of Poultry Waste, Digestion of Rabbit and Pig Waste, Chemical Composition of Palm Oil Mill Effluent, Humic Substances from Composed Barks, Humic Substances from Decomposing Bark, Particle Size and Tomato Waste Digestion, Humic Acids on Hydrolysis of Potato Protein, Effects of Composts on Wheat Yields, Production of Oxytetracycline, Oxytetracycline Production, Production of oxytetracycline from agricultural wastes, Use of Manure in Fish Farming, Bacteria in Swine Waste, Poultry Waste Water as Broiler Feeds, Utilization of Indian Wastes in Livestock Feeds, Methane from Cattle Waste, Methane Production from Cattle Waste, Treatment of Milking Parlour Wastewater, Pig Liquid Manure, UASB Treatment of Wastes, Digestion of Poultry Litter, Beef-Cattle Manure Slurries, New small scale ideas for Biological Treatment, Business Ideas for Biological Treatment, How to start a Biological Treatment Plant, Start Your Own Biological Treatment Business, Biological Treatment Business Plan, Business plan for Organic Waste for Biological Treatment, Small Scale Industries in India, Organic Waste for Biological Treatment Based Small Business Ideas in India, Small Scale Industry You Can Start on Your Own, Business plan for small scale industries, Profitable Small Scale Manufacturing, How to Start a Small Business in India, Free Manufacturing Business Plans, Small and Medium Scale Manufacturing, Profitable Small Business Industries Ideas, Business ideas for Startup, Detailed Project Report on Biological Treatment, Project Report on Biological Treatment, Pre-Investment Feasibility Study on Oxytetracycline Production, Techno-Economic feasibility study on Oxytetracycline Production, Feasibility report on Piggery Waste Management, Free Project Profile on Piggery Waste Management, Project profile on Organic Waste for Biological Treatment, Download free project profile on Oxytetracycline Production
Proceedings of a workshop held in Brussels, Belgium, 26-27 October 1988, under the auspices of COST European Cooperation in Scientific and Technology Research - COST 641 and 681.
Healthcare facilities, medical laboratories and biomedical research facilities generate large amounts of biomedical waste. Poor management of the waste can cause serious health and environmental hazards. This book aims to cover the latest technologies and innovations for sustainable management. It covers bioremediation processes, plastic waste recycling, and metal recovery. It also discusses waste monetization, such as conversion into energy.
The cumulative effects of pollution have led, in recent years, to increased public concern, which is resulting in stricter legislation on the discharge of wastes in whatever state they are present: gaseous, liquid or solid. The treatment and disposal of wastes has become one of the most important problems facing mankind. This is a problem which will not disappear, and could even worsen, if it is not faced with resolution by all the main parties involved: consumers, governments, producers and scientists. Some wastes could be reused, producing some economic return which could pay for the waste-treatment process. In the best of cases, this could become an economically attractive recycling operation. However, in many situations, waste treatment is considered to be an unproductive process which entails additional costs to an otherwise productive operation. Methods for the removal and purification of wastes (including those considered to be 'toxic wastes', the most dreaded form of pollution), if developed at all, suffer from serious limitations. Two of these are the high energy input into the process and, after the contaminants have been removed, the lingering problem of what to do with them, as they will then exist as some kind of concentrate. The ideal solution is none other than a natural, biological process to degrade wastes. Fortunately, mankind is increasingly choosing that option, as exemplified by the general acceptance of the role of biotechnology in modern society.
