Recent trends and innovations in sustainable treatment technologies for heavy metals dyes and other xenobiotics / Biswanath Bhunia and Muthusivaramapandian Muthuraj.

Format:

Book

Author/Creator:

Bhunia, Biswanath, author.

Muthuraj, Muthusivaramapandian, author.

Language:

English

Subjects (All):

Dyes and dyeing.

Heavy metals.

Physical Description:

1 online resource (243 pages)

Edition:

First edition.

Place of Publication:

Singapore : Bentham Science Publishers, [2022]

Summary:

This book integrates knowledge about innovative technologies developed in the past decade with information about commercial-scale processes. It is written with the objective to help readers to understand the potential of achieving sustainability and high efficiency in wastewater treatment. The book presents nine chapters. Chapter 1 details the types of wastewater, its characteristics, and the major commercial-scale strategies employed to treat wastewater. Chapter 2 details the different types of physicochemical methods utilized for the remediation of heavy metals, dyes, and xenobiotics. Chapters 3 and 4 highlight innovations in the advanced oxidation process and adsorption for remediation of such complex molecules, respectively. Chapters 5, 6, and 7 highlight the recent innovations in bioremediation of xenobiotics, heavy metals, and dyes, respectively. Finally, chapters 8 and 9 discuss the latest technologies, prevailing bottlenecks, and the path ahead towards commercial viability and environmental sustainability in both physico-chemical and biological treatment processes.

Contents:

Cover

Title

Copyright

End User License Agreement

Contents

Foreword

Preface

List of Contributors

Wastewater Types, Characteristics and Treatment Strategies

Uttarini Pathak1, Avishek Banerjee2, Subham Kumar Das3, Teetas Roy3 and Tamal Mandal1,*

1. INTRODUCTION

2. CHARACTERIZATION

2.1. Coke Oven Wastewater

2.2. Rice Mill Wastewater

2.3. Pharmaceutical Wastewater

2.4. Leather Industry Wastewater

3. TREATMENT STRATEGIES

3.1. Coke Oven Wastewater

3.2. Rice Mill Wastewater

3.3. Pharmaceutical Wastewater

3.4. Leather Industry Wastewater

CONCLUSION

CONSENT FOR PUBLICATION

CONFLICT OF INTEREST

ACKNOWLEDGEMENT

REFERENCES

High Gravity Technology for Improving Efficiency of Wastewater Treatment Processes

Sudhanya Karmakar1, Avijit Bhowal1,2,*, Papita Das1,2 and Abhijit Mondal3

2. CONVENTIONAL WASTEWATER TREATMENT PROCESS AND EQUIPMENT

2.1. Adsorption

2.2. Air Stripping

2.3. Liquid-liquid Extraction

2.4. Emulsion Liquid Membrane

2.5. Advanced Oxidation Process

2.6. Fenton Oxidation

2.7. Ozonation

2.8. Photocatalytic Treatment

3. PROCESSES IN HIGH GRAVITY EQUIPMENT

3.1. Rotating Packed Bed

3.2. Micromixing

3.3. Gas and Liquid Mass Transfer Coefficient

3.4. Allowable Throughput

3.5. Spinning Disc Reactor

Recent Trends in Advanced Oxidation and Catalytic Processes for Removal of Heavy Metals, Dyes, and Xenobiotics

Rupak Kishor1,*, Suneeta Kumari2, Muthusivaramapandian Muthuraj3 and Narayanasamy Selvaraju4

2. ADVANCED OXIDATION PROCESS (AOP)

1.1. Ozone Assisted AOPs

1.2. Ultraviolet Assisted AOPs

1.3. Fenton Assisted AOPs

1.4. Sonolysis Assisted AOPs

1.5. Photocatalysis Assisted AOPs.

1.6. Sulfate Radical-based AOPs

2. REMOVAL OF DYES BY AOPS APPLICATION

2.1. Removal of Dyes Using Ozonation Assisted AOPs

2.2. Removal of Dye Using UV-assisted AOPs

2.3. Removal of Dye Using Fenton Oxidation

2.4. Removal of Dye Using Sonolysis

2.5. Photocatalytic Removal of Dyes

3. REMOVAL OF XENOBIOTICS BY AOPS APPLICATION

3.1. Removal of Xenobiotics by Ozonation-based AOPs

3.2. Removal of Xenobiotics by UV-based AOPs

3.3. Removal of Xenobiotics by Fenton and Photo-Fenton Process

3.4. Removal of Xenobiotics by Sonolysis

3.5. Removal of Xenobiotics by Photochemical Degradation

4. REMOVAL OF HEAVY METAL USING AOPS

4.1. Heavy Metal Removal Using Ozonation-based AOPs

4.2. Heavy Metal Removal Using UV-assisted and Photocatalytic AOPs

4.3. Heavy Metal Removal Using Fenton Oxidation-based AOPs

Developments in Adsorption Technologies for Removal of Heavy Metals, Dyes, and Xenobiotics

Abhijit Chatterjee1,*, Uttara Mahapatra2 and Silke Schiewer3

2. PREPARATION, CHARACTERIZATION, AND MECHANISM OF VARIOUS ADSORBENTS

2.1. Activated Carbon (GAC, PAC, Biochar)

2.2. Zeolites and Clay Materials

2.3. Biosorbent (Agricultural Residue and Microbial Biomass)

2.4. Carbon Nanotubes

2.5. Graphene

2.6. Hybrid

3. INFLUENCE OF PROCESS PARAMETERS

4. MODELING OF ADSORPTION PROCESS

4.1. Adsorption Isotherm

4.2. Adsorption Kinetics

4.2.1. Surface Reaction Models (SRM)

4.2.2. Mass Transfer Models (MTM)

4.3. Example of Unconventional Mathematical Modeling

Bioderived and Bioconjugated Materials for Remediation of Heavy Metals and Dyes from Wastewater.

S.R. Joshi1,* and Debajit Kalita1,2

1.1. Heavy Metals from Mining, Processing and Industrial Effluents

1.2. Heavy Metals Used in Agriculture

1.3. Air Mediated Sources of Heavy Metals

1.4. Sources of Dyes

2. REMEDIATION AND RELATED TECHNOLOGY

2.1. Phytoextraction

2.2. Phytostabilization

2.3. Rhizofiltration

2.4. Phytovolatilization

2.5. Phytotransformation/ Phytodegradation

2.6. Plant-based Remediation of Heavy Metals and Dyes

2.7. Whole Plant for Dye Removal

2.8. Plant Derived Material for Heavy Metal

2.9. Plant Derived Material for Dye

2.10. Plant Synthesized/Conjugated Material for Heavy Metals

2.11. Plant Synthesized/Conjugated Material for Dye Removal

3. MICROBIAL BASED REMEDIATION

3.1. Whole Cells for Heavy Metals

3.2. Whole Cells for Dye Removal

3.3. Microbial Derived/Conjugated Remediation of Heavy Metals

3.4. Microbial Derived/Conjugated Remediation of Dye

3.5. Microbial Synthesized/Conjugated Material for Heavy Metals

3.6. Microbial synthesized/conjugated Material for Dye

ACKNOWLEDGEMENTS

Trends in Bioremediation of Dyes from Wastewater

Chandrani Debnath1, Biswanath Bhunia1, Bikram Basak2 and Muthusivaramapandian Muthuraj1,*

2. BIOLOGICAL TREATMENT OF DYES

2.1. Biosorption of Dyes

2.1.1. Biomaterials for Adsorption

2.1.2. Factors Influencing Biosorption of Dyes

2.2. Bioaccumulation and Degradation of Dyes

2.2.1. Factors Affecting Biodegradation

2.3. Biochar, and Biochar-based Nanocomposites

2.4. Porous Materials and Metal-organic Frameworks (MoFs)

2.5. High-performance Forward-osmosis Membrane

3. SUSTAINABLE STRATEGIES FOR BIOREMEDIATION OF DYES

4. BOTTLENECKS &amp

FUTURE PROSPECTS

CONCLUSION.

CONSENT FOR PUBLICATION

Bottlenecks in Sustainable Treatment of Wastewaters Using Physico-Chemical Processes and Future Prospects

Nibedita Mahata1,*, Biswanath Bhunia2, Muthusivaramapandian Muthuraj2 and Ramesh Kumar3

2. BOTTLENECKS OF PHYSICO-CHEMICAL WASTEWATER TREATMENT PROCESS

2.1. Membrane Filtration

2.2. Activated Carbon Filtration

2.3. Adsorption

2.4. Advanced Oxidation Processes

2.5. Dissolved Air Floatation (DAF)

2.6. Coagulation-Flocculation and Sedimentation

2.7. Electrocoagulation (EC) Process

3. CRITERIA FOR SUSTAINABLE WASTEWATER TREATMENT TECHNOLOGIES

3.1. Performance

3.2. Cost

3.3. Sustainability

3.3.1. Resource Recovery

3.3.2. Energy Management

3.3.3. Solid Volume Reduction

3.4. Prospects in Physico-chemical Remediation

Sustainable Mitigation of Wastewater Issues Using Microbes: Hurdles and Future Strategies

Bidhu Bhusan Makut1, Mayurketan Mukherjee2, Gargi Goswami2 and Debasish Das1,2,*

2. BIOLOGICAL TREATMENT

2.1. Bacterial Treatment

2.1.1. Challenges Associated with Bacterial Bioremediation

2.2. Treatment of Wastewater Using Microalgae

2.2.1. Challenges Associated with Microalgal Bioremediation

2.3. Mycoremediation of Wastewater Treatment

3. CONSORTIUM AIDING ENHANCED BIOREMEDIATION

3.1. Pivotal Role of Microalgae-Bacteria Consortium in Wastewater Treatment

3.1.1. Mutualistic Association

3.2. Microalgae-Bacteria Based Wastewater Treatment

3.3. Confrontation Associated with Microalgae-Bacteria Consortium Towards Bioremediation

CONCLUDING REMARKS

Subject Index.

Back Cover.

Notes:

Includes bibliographical references.

Description based on publisher supplied metadata and other sources.

Description based on print version record.

ISBN:

9789815049725

9815049720

OCLC:

1369653110