Membrane-based Hybrid Processes for Wastewater Treatment

Coordinators: Shah Maulin P., Rodriguez-Couto Susana

Language: English
Cover of the book Membrane-based Hybrid Processes for Wastewater Treatment

Subjects for Membrane-based Hybrid Processes for Wastewater Treatment

Keywords

?AOP; Activated carbon; Activated sludge; Adsorbent; Adsorption; Anion separation; Biodegradation; Biofilm; Biofilm assay; Biofiltration; Biomethane; Bioreactor; Bioremoval; COD removal; Carbon nanotubes; Carriers; Catalytic nanoparticles; Chemical interactions; Coagulation; Contaminants; Counterions; Cyanide; Denitrification; Donnan effect; Donnan exclusion; Donnan potential; Dye removal; Eco-green environment; Energy; Environment; Environmental pollutants; Enzymatic catalysis; Filtration; Fluoride; Graphene; Heavy metals; Human health; Hybrid membrane; Hybrid membranes; Hybrid process; Hybrid processes; Hybrid systems; Hybrid technology; Improved surface properties; Industrial effluent; Industrial waste effluent; Industrial wastewater; Kinetics; Liquid effluent; MBBRs; MBR; Mass transfer processes; Matrix material; Mechanism; Membrane; Membrane bioreactor; Membrane bioreactor (MBR); Membrane bioreactors; Membrane distillation; Membrane fouling; Membrane process; Membrane processes; Membrane separation processes; Membrane technology; Membrane-based hybrid process; Membranes; Metal-finishing; Modeling; Municipal wastewater; Nanocomposite membrane; Nanofiltration; Nanomaterials; Nanoparticles; Nanotechnology; Nanotechnology-enabled filtration; Nitrification; Nutrient recovery; Oil; Osmosis; Paint industry effluent; Permeate flux; Pharmaceuticals; Photocatalysis; Pollution; Polymeric and ceramic membrane structure; Polyvinylidene fluoride; Pressure driven membrane; Reuse/recycling; SAB; Scale-up; Separation efficiency; Submerged MBR; Textile industry; Thermally driven membrane; Thermodynamic functions; Thin film nanocomposite; Types of biofilm bioreactors; Ultrafiltration; Waste water treatment; Wastewater

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730 p. · 19x23.3 cm · Paperback
Membrane-Based Hybrid Processes for Wastewater Treatment analyzes and discusses the potential of membrane-based hybrid processes for the treatment of complex industrial wastewater, the recovery of valuable compounds, and water reutilization. In addition, recent and future trends in membrane technology are highlighted. Industrial wastewater contains a large variety of compounds, such as heavy metals, salts and nutrients, which makes its treatment challenging. Thus, the use of conventional water treatment methods is not always effective. Membrane-based hybrid processes have emerged as a promising technology to treat complex industrial wastewater.

1. The industrial development of polymeric membranes and membrane modules for reverse osmosis and ultrafiltration2. Moving bed biofilm reactors3. Biofilms, filtration, microbial kinetics and mechanism of degradation: a revolutionary approach4. Wastewater treatment by membrane bioreactor as potent and advanced technology5. Catalytic membranes for the treatment of oily wastewater6. Application of membrane-based hybrid process on paint industry wastewater treatment7. Application of nanotechnology in membrane-based wastewater treatment: a critical review8. Application of nanoparticles in polymeric and ceramic membrane structure in wastewater treatment9. Anaerobic membrane bioreactor for wastewater treatment: present state of the art10. Permselective membranes for wastewater treatment11. Membrane-based hybrid processes in industrial waste effluent treatment12. Membrane reactors13. Hybrid membrane process: an emerging and promising technique toward industrial wastewater treatment14. Pharmaceuticals in water: Equilibrium and thermodynamic aspects of adsorption on activated carbon for wastewater treatment15. Hybrid membrane technique: a technological advancement of textile waste effluent treatment16. Industrial wastewater treatment by membrane process17. Synthesis of thin film nanocomposite membranes and their application in dye removal from wastewater18. Hybrid membrane technology: demand of present wastewater scenario19. Membrane-based technologies for industrial wastewater treatment and resource recovery20. Membrane bioreactors for wastewater treatment21. Environmental aspects of fluoride contamination and treatment of wastewater using hybrid technology22. Sustainable biological approach for removal of cyanide from wastewater of a metal-finishing industry23. Hybrid membrane technology: an alternative to industrial wastewater treatment 24. Developments in membrane bioreactor technologies and evaluation on case study applications for recycle and reuse of miscellaneous wastewaters25. Modeling aspects of membrane-based industrial wastewater treatment26. Aerobic membrane bioreactor for the efficient wastewater treatment: recent advances27. Emerging nano enhanced membranebased hybrid processes for complex industrial wastewater treatment28. Nanomembranes for ultrapurification and water treatment

Dr. Maulin P. Shah is Chief Scientist and Head of the Industrial Waste Water Research Lab, Division of Applied and Environmental Microbiology Lab at Enviro Technology Ltd., Ankleshwar, Gujarat, India. His work focuses on the impact of industrial pollution on the microbial diversity of wastewater following cultivation-dependent and cultivation-independent analysis. His major work involves isolation, screening, identification, and genetically engineering high-impact microbes for the degradation of hazardous materials. His research interests include biological wastewater treatment, environmental microbiology, biodegradation, bioremediation, and phytoremediation of environmental pollutants from industrial wastewaters.


Susana Rodríguez-Couto (female) got her B.Sc. and M.Sc. in Chemistry (Industrial Chemistry) from the University of Santiago de Compostela in 1992 and her Ph.D. in Chemistry in 1999 from the University of Vigo, obtaining the maximal grade (magna cum laude) and, in addition, she was awarded with the Extraordinary Prize for Doctoral Thesis in Chemistry. She worked as an Associate Professor and an Isidro Parga Pondal Senior Researcher at the University of Vigo (2000-2004), as a Ramón y Cajal Senior Researcher at Rovira i Virgili University (2004-2008) and as an Ikerbasque Research Professor (2009-2019). She has also worked as an Invited Researcher at the Institute from Environmental Biotechnology, Graz University of Technology (Austria) and at the Department of Biological Engineering, University of Minho (Portugal). In 2008, she received the I3 Professor from the Spanish Ministry of Science and Education to the recognition of an outstanding research activity. In March 2021 she is joining LUT School of Engineering Science at Mikkeli, Finland, as a Full Professor in biological water treatment. She has published more than 140 articles in highly reputed international journals (h index 42). She is editor of several journals (3Biotech, Frontiers)
  • Discusses the properties, mechanisms, advantages, limitations and promising solutions of different types of membrane technologies
  • Addresses the optimization of process parameters
  • Describes the performance of different membranes
  • Presents the potential of Nanotechnology to improve the treatment efficiency of wastewater treatment plants (WWTPs)
  • Covers the application of membrane and membrane-based hybrid treatment technologies for wastewater treatment
  • Includes forward osmosis, electrodialysis, and diffusion dialysis
  • Considers hybrid membrane systems expanded to cover zero liquid discharge, salt recovery, and removal of trace contaminants