This book discusses new and innovative trends and techniques in the removal of toxic and refractory pollutants by means of various microbial biotechnology processes from wastewater, both on the laboratory and industrial scales. The book also highlights the main factors contributing to the removal of toxic pollutants as well as recycling, environmental impact, and wastewater policies after heavy metal removal. In addition, it assesses the potential application of several existing bioremediation techniques and introduces new cutting-edge emerging technologies. This book significantly contributes to the wastewater treatment plant industry so that the treatment systems can serve better and more resiliently for the purpose. This book is designed for engineers, scientists, and other professionals who are seeking introductory knowledge of the principles of environmental bioremediation technology and for students who are interested in the environmental microbiology and bioremediation fields.

Current use of the ammonia oxidizing bacteria (AOB) within biological wastewater treatment system is incomplete due to limitations of current culture-based techniques. This book offers an overview of new nitrification technologies via the use of AOB in the removal of ammonia nitrogen from wastewater. The application of new approaches based on AOB leads to greater ammonia nitrogen removal and results in more efficient wastewater treatment.

This book examines various unique applications and their effectiveness of constructed wetlands for the treatment of complex and heavily polluted wastewater from industrial sources. It also highlights the technological and advanced knowledge in application of constructed wetlands through different microbiological and advanced biochemical technologies. Special attention is paid to suspended solids, organic matter, and nutrient removal. Deep insights are provided for facilities such as those in oil and gas industries, agro-industry, paper and pharmaceutical manufacturing, the textile industry, wineries, breweries, and sludge treatment, among others. Constructed wetlands are low-cost and sustainable systems for wastewater treatment. Traditionally, they have been used for urban and domestic wastewater treatment, but in the last two decades, applications for industrial wastewater treatment have increased due to the advances of the technology and extended research in the field. The advances have also been encouraged by the economic, environmental, and societal advantages over conventional technologies. This book helps academicians and industrialists obtain detailed knowledge about constructed wetlands in the field of wastewater treatment.

Ammonia in wastewater causes the eutrophication of water bodies and the subsequent depletion of dissolved oxygen. In addition, certain forms of nitrogen such as ammonia, nitrite, and nitrate are highly toxic to aquatic life. Although there are several biological and physical–chemical techniques for the removal of ammoniacal nitrogen compounds, including air stripping and breakpoint chlorination, which have been widely applied, a microbiological or microbe-based approach is attractive because it is based on sustainable technologies. In this regard, ammonia-oxidizing bacteria have recently gained great interest, specifically in wastewater treatment plants for the removal of ammoniacal nitrogen especially, owing to its relatively low capital cost, eco-friendliness, and high efficiency when compared with conventional cleanup technologies. This book provides specific and advanced knowledge on the microbial ecology of ammonia-oxidizing bacteria and their diversity and functions in the treatment of toxic pollutants present in wastewater. The book thus serves as a valuable resource for engineers, scientists, and managers who require an excellent introductory and advanced knowledge of the field, professionals who are working or interested in the environmental microbiology or bioremediation field, and students learning about environmental biotechnology and microbiology.

Microbial technology using live, naturally occurring microorganisms in industrial wastewater treatment, is the most effective and innovative method to degrade environmental pollutants such as heavy metals, radionuclides, xenobiotic compounds, organic waste, and pesticides, or to prevent their contamination of the environment. The technology includes several techniques such as biostimulation, biogeneration, bioaccumulation, and biosorption. This book describes the limitations and challenges associated with some generally accepted bioremediation strategies and evaluates the possible applications of these corrective strategies to eliminate toxic pollutants from the environment. The environmental contamination by both natural and anthropogenic sources is, nowadays, an international concern. To decontaminate soils, sediments, and water polluted by anthropogenic activities, scientists and technologists have developed various technologies over the years; however, not only do we have to pay a high cost for physical and chemical environmental technologies but also they sometimes are not ecological or safe. Therefore, we have realized the necessity to develop viable technologies that use microbes and plants to avoid these issues. This book is designed for engineers, scientists, and other professionals who are seeking introductory and advanced knowledge of the principles of nanotechnology, and those who work or are interested in the environmental microbiology or bioremediation field.

This book explores the production and applications of biochar. This material is used to remove contaminants from industrial effluent and to reutilize waste sludge in the production of biofuel/bioenergy. The treatment of wastewater and reuse of waste sludge in value added products manufacturing and environmental clean-up is explored. This book provides a roadmap for future strategies for pollution abatement and sustainable development.

This book covers the latest development in the biotechnological application of extremophiles. Along with this the impact of climate change and environmental pollution on loss of diversity of extremophiles is also discussed. This is crucial as the loss of this diversity is related with the loss of many bioactive compounds and bacteria of ecological importance. This volume outlines applications of extremophiles in biotechnology, nanotechnology, and bioremediation.

Remediation of wastewater is important to ensure that pollutants generated in industry do not effect our environment negatively. Traditional wastewater remediation is not a sustainable process, however by using biological means the sustainability can be improved. This book explores how bioremediation biotechnology is used to remove pollutants in wastewater. Both conventional methods bioremediation technologies are discussed.

This book identifies emerging technologies that allow the reuse and regeneration of industrial wastewater with innovative and applied approaches throughout the wastewater treatment cycle. Today, it is increasingly clear that treated urban wastewater, whose reuse has become an important component of long-term water management worldwide, is a key source of chemical pollutants and emerging biological concerns. Current water-quality guidelines for reclaimed wastewater predominantly address the risks associated with the presence of microbial organisms and chemical parameters such as biological oxygen demand, chemical oxygen demand, E. coli and worms, and in some cases heavy metals; however, they are insufficient for the full evaluation of risks. The global growth of population is concentrated in urban areas; therefore, most of the challenges and solutions related to wastewater reside in urban treatment plants. Unless wastewater management and wastewater governance processes are significantly improved within a decade, it is likely that our societies will face severe and prolonged water insecurity and urban floods. The application of sustainable technologies can eliminate or minimize micro-contaminants in wastewater. Several organizations focus on the potential impacts to humans and their environments by wastewater reuse. This book gathers new research and reviews work from researchers and scientists to identify the main barriers and limitations that will need to be overcome, so that wastewater reuse strategies gain more momentum and will be adopted more efficiently worldwide. The book is designed for engineers, scientists, and other professionals who are seeking an excellent introduction to and basic knowledge of the principles of environmental bioremediation technologies.

Microbial or biological degradation has long been the subject of active concern, and the rapid expansion and growing sophistication of various industries in the last century has significantly increased the volume and complexity of toxic residues of wastes. These can be remediated by plants and microbes, either natural origin or adapted for a specific purpose, in a process known as bioremediation. The interest in microbial biodegradation of pollutants has intensified in recent years in an attempt to find sustainable ways to clean contaminated environments. These bioremediation and biotransformation methods take advantage of the tremendous microbial catabolic diversity to degrade, transform or accumulate a variety of compounds, such as hydrocarbons, polychlorinated biphenyls, polaromatic hydrocarbons pharmaceutical substances, radionuclides and metals. Unlike conventional methods, bioremediation does not physically disturb the site. This book describes the basic principles of biodegradation and shows how these principles are related to bioremediation. Authored by leading, international environmental microbiologists, it discusses topics such as aerobic biodegradation, microbial degradation of pollutants, and microbial community dynamics. It provides valuable insights into how biodegration processes work and can be utilised for pollution abatement, and as such appeals to researchers and postgraduate students as well as experts in the field of bioremediation.

This book summarizes the advanced sustainable trends in removing toxic pollutants by environmental and biotechnological processes from both industrial wastewater and sewage wastewater. The book also provides an assessment of the potential application of several existing wastewater bioremediation techniques and introduces new cutting-edge technologies. Among other valuable information covered, here are the methods, procedures, materials (especially low-cost materials originating from industrial and agricultural waste), management of wastewater containing toxic pollutants, and valorization possibilities of waste resulting from the removal of toxic pollutants from wastewater. Tonnes of hazardous waste pollutants released by industries are a challenge worldwide. With the ever-growing population and shrinking landfill areas, managing the disposal of pollutants is a matter of severe concern. Industrial wastewater treatment, recycling, and reuse are serious issues in today’s context, not just to protect the environment from pollution, but also to conserve water resources so that water stress is reduced. This book is designed for engineers, scientists, and other professionals and serves as a good summary of the current state-of-the-art and innovative research challenges to control pollution for coming generations.

Increasing population and industrialization are the key pollutant contributors in water bodies. The wastes generated by industries are highly hazardous for humans and the ecosystem and require a comprehensive and effective treatment before being discharged into water bodies. Over the years, many up gradations have been introduced in traditional water treatment methods which were expensive and ineffective especially for removal of toxic pollutants. Phycoremediation has been gaining attention due to its mutual benefit in wastewater treatment and for valuable algae biomass production. Wastewater, especially sewage and industrial effluents, is rich in pathogenic organisms, organic and inorganic compounds and heavy metals that adversely affect human and aquatic life. Microalgae use these inorganic compounds and heavy metals for their growth. In addition, they also reduce pathogenic organisms and release oxygen to be used by bacteria for decomposition of organic compounds in a secondary treatment. In this book, the potential of microalgae in wastewater treatment, their benefits, strategies, and challenges are discussed. The increasing need of finding innovative, low-cost, low-energy, sustainable and eco-friendly solutions for wastewater treatment makes the publication of a book on phycoremediation timely and appropriate. Features: (1) Deals with the most emerging aspects of algal research with special reference to phycoremediation. (2) Studies in depth diversity, mutations, genomics and metagenomics study (3) An eco-physiology, culturing, microalgae for food and feed, biofuel production, harvesting of microalgae, separation and purification of biochemicals.

Comprehensive reference examining activated sludge technologies in industrial wastewater treatment, combining a theoretical framework with practical methodologies Application of Sewage Sludge in Industrial Wastewater Treatment provides a roadmap to the methodologies for the treatment of industrial wastewaters from several major sectors integrating theory and practice, highlighting the importance of sewage sludge technologies in industrial wastewater treatment to clean up the environment from pollution caused by human activities, and assessing the applications of several existing activated sludge techniques and introduces new emerging technologies. All discussion within the text is based on a solid theoretical background. Application of Sewage Sludge in Industrial Wastewater Treatment covers key topics such as: Issues related to activated sludge treatment, such as biodegradability-based characterization, modeling, assessment of stoichiometric, and kinetic parameters and design Issues related to industrial pollution control, such as in-plant control, effect of pretreatment, and more Recently increasing quantity and complexity of toxic effluents, which can be bio remediable for plants and suitable microbes, whether natural or customized for specific purposes Ecological, profitable, and natural solutions designed to eliminate heavy metals, radionuclides, xenobiotic compounds, organic waste, pesticides, and more This reference provides an essential, one-of-a-kind, integrated approach for environmental microbiologists, biochemical engineers, environmental engineers, effluent treatment plant operators, and biologists and chemists at wastewater treatment plants.

The book highlights the importance of emerging technologies in wastewater treatment plant to clean up the environment from pollution caused by human activities It assesses the potential application of several existing bioremediation techniques and introduces new emerging technologies It is an updated vision of the existing emerging technologies in environmental bioremediation strategies with their limitations and challenges and their potential application to remove environmental pollutants It also introduces the new trends and advances in environmental bioremediation with thorough discussion of recent developments in this field. Highlights the importance of bioremediation to deal with the ever-increasing number of environmental pollutants.

The ever-increasing number of pollutants discharged into the environment drives the search for new treatment technologies or the modification of the existing ones. In this sense, innovation in bio nanofiltration systems seems very promising and therefore, a book on the current advances and innovations on his topic is highly appropriate. Bio nanofiltration is a relatively emerging new technology applied to the treatment of wastewater and other toxic compounds. In the last two decades, this technology has begun to emerge as an economically viable process to treat the great variety of recalcitrant pollutants discharged into the environment. Thus, the US biofiltration market is speculated to reach over $100 million by 2020. This book aims to present how innovation in bio nanofiltration can provide effective solutions to overcome the serious problem of water pollution worldwide. The removal of contaminants will be the result of the combined effects of biological oxidation, adsorption, and filtration processes. Features: Describes the microbial ecology of bio nanofiltration Describes the modelling of bio nanofiltration Describes designing of bio nanofillers

Provides exhaustive coverage of Biochar and its production and properties. Highlights use of biochar in pollution control and environment protection. Covers use of agricultural waste /waste biomass for dye decolorization and degradation. Explores synergistic approaches for contaminants removal for better insights into basic and advanced biotechnological applications. Describes how biochar treatment can be successfully applied for reuse of wastewater and contaminated soil eco-restoration and environment protection.

Bio-refinery approach of microbial fermentation, production of  biogas, bioenergy, enzymes, bioactive molecules, agricultural nutrient and many more, which is presently restricted to specific journals, review articles and research papers in conference proceedings. Hence, my effort is to provide a complete and globally available advance knowledge in wastewater treatment with an aim of recovery of value added products. This will help in designing new approaches of waste water treatment with this value added thoughts. Thus, it will be a boon for a concern broad range of readers and industry professionals to their means of technology development for pollution prevention and economic growth of the country.

This book details microbial remediation of azo dyes from wastewater including information on existing methods and technologies, their graduation, the emergence of new technologies, industrial practices, and real-case studies. Emphasis is placed on industrial applications and the elimination of toxic pollutants from wastewater through bacterial approach. Specific aspects discussed include effective separation through new adsorbents / newcomers, ion exchange process, coagulation / formulations, separations, and biological methods from wastewater. This book explains a paradigm shift towards the recovery of materials and energy from azo dye containing wastewater. Features: Provides information on the topic of prokaryotic-based technologies for azo dye degradation in wastewater treatment plant. Describes microbial enzymes and their role in bioremediation of environmental pollutants. Covers industrial acid mine tailing wastes, plastic wastes, distillery, and pulp paper industry effluent. Discusses critical insight into limitations of related technologies. Explains concepts through illustrations, figures, tables, and trivia boxes. This book aims at Researchers, Professionals, Graduate Students in Bioremediation and Environmental Protection, Waste Management, Applied Microbiology, Botany and Plant Biotechnology.

Provides exhaustive information on the use of algae for the simultaneous treatment and resource recovery of wastewater. Discuses algae, microalgae, and cyanobacteria applications in-detail. Presents critical insight into limitations of the prevalent technologies. Reviews methodology of advanced technologies. Includes illustrations and interesting trivia boxes throughout the book.

This book discusses new and innovative trends and techniques in the removal of toxic and or refractory pollutants through various environmental biotechnological processes from wastewater, both at the laboratory and industrial scale. It focuses primarily on environmentally-friendly technologies which respect the principles of sustainable development, including the advanced trends in remediation through an approach of environmental biotechnological processes from either industrial or sewage wastewater. Features: Examines the fate and occurrence of refractory pollutants in wastewater treatment plants (WWTPs) and the potential approaches for their removal. Highlights advanced remediation procedures involving various microbiological and biochemical processes. Assesses and compares the potential application of numerous existing treatment techniques and introduces new, emerging technologies. Removal of Refractory Pollutants from Wastewater Treatment Plants is suitable for practicing engineers, researchers, water utility managers, and students who seek an excellent introduction and basic knowledge in the principles of environmental bioremediation technologies.

Provides practical solutions for the treatment and recycling of distillery waste illustrated by specific case studies. Focuses on recent industry practices and preferences, along with newer approaches for wastewater treatment. An instructive compilation of treatment approaches, including advanced physicochemical and integrated/sequential methods. Covers biocomposting of sludge and effluent and biodiesel production from distillery waste for recycling and sustainable development. Emphasizing the relationship of metagenomics with organometallic compounds of distillery waste. Discusses the role of ligninolytic enzymes and bioreactors in distillery wastewater treatment.

1. Discusses the properties, mechanisms, advantages, limitations and promising solutions of different types of membrane technologies 2. Addresses the optimization of process parameters 3. Describes the performance of different membranes 4. Presents the potential of Nanotechnology to improve the treatment efficiency of wastewater treatment plants (WWTPs) 5. Covers the application of membrane and membrane-based hybrid treatment technologies for wastewater treatment

This book provides essential information on the role of phytonanotechnology in the removal of environmental pollutants and covers recent advances in experimental and theoretical studies on plant-derived nanoparticles. It also discusses their current and potential applications and challenges.The combination of nanotechnology and phytoremediation, which is called phytonanotechnology, have the potential to remove contaminants from the environment or degrade them. The efficiency of contaminant removal can be improved by combining both methods as they are complementary to each other.Phytonanotechnology offers the advantages of increased bioavailability, prolongation of heavy metal absorption time, and multiple metal removal, all contributing to improved efficacy and decreased toxicity in plants and surroundings. Therefore, there is immense scope for nature-derived molecules to be formulated into nanotechnology-based phytoremediation approaches targeting the specific heavy metal removal from effluents and surroundings. This encourages research initiatives to synthesize more phytonanotechnology based uptake plant systems with high efficiency. Efficient formulation targeting strategies and the evaluation of targeting efficiency of phytonanotechnology, conforming to international standards of their toxicology and biocompatibility, could pave the way for heavy metal uptake and removal by plant-based systems.This book serves as a valuable resource for postgraduate students, environmental scientists and materials scientists in academia and corporate research.

Describes the state-of-the-art techniques and the application of omics tools in wastewater treatment reactors (WWTRs) Includes both the theoretical and practical knowledge on the fundamental roles of microorganisms in WWTRs Discusses environmental microbial community proteomics Covers relating function and community structure of complex microbial systems using neural networks Reviews the economics of wastewater treatment and the development of suitable alternatives in terms of performance and cost effectiveness

Illustrates the importance of various advance oxidation processes in effluent treatment plant Points out the reuse of the treated wastewater through emerging advance oxidation technologies for effluent treatment plant Highlights the recovery of resources from wastewater Pays attention to the occurrence of novel micro-pollutants Emphasizes the role of nanotechnology in bioremediation of pollutants Introduces new trends in environmental bioremediation