Green and Sustainable Approaches Using Wastes for the Production of Multifunctional Nanomaterials

1st Edition - January 19, 2024
Editors: Abhishek Kumar Bhardwaj, Kuldip Dwivedi, Mika Sillanpaa, Arun Lal Srivastav
Language: English
Paperback ISBN:
9 7 8 - 0 - 4 4 3 - 1 9 1 8 3 - 1
eBook ISBN:
9 7 8 - 0 - 4 4 3 - 1 9 1 8 4 - 8

Green and Sustainable Approaches Using Wastes for the Production of Multifunctional Nanomaterials focuses on the examination of green synthesis utilizing green waste materi… Read more

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Green and Sustainable Approaches Using Wastes for the Production of Multifunctional Nanomaterials focuses on the examination of green synthesis utilizing green waste materials derived from home and industrial applications. This book also examines the current state of material generations, future problems and their industrial constraints, and the synthesis of NMs for various applications such as medicinal, agriculture, environmental, food and beverage storage, and so on. The book includes the most recent practical and theoretical aspects of the use of waste materials released in the fabrication of various types of valuable nanomaterials, such as metal, metal oxide, polymeric, and graphene, among others. This is a relatively new concept in waste utilization, and green synthesis is a viable resource in making NPs. This book will also be valuable for waste management professionals who need proper disposal techniques for by-products.

Cover image
Title page
Table of Contents
Copyright
List of contributors
Preface
Chapter 1. Global status of biogenic and nonbiogenic waste production and their employability in nanomaterial production
Abstract
1.1 Introduction
1.2 Biogenic waste
1.3 Nonbiogenic waste
1.4 National and International effort in waste management
1.5 Disposal
1.6 Future perspective
1.7 Concluding remarks
References
Chapter 2. Sustainable advances in the synthesis of waste-derived value-added metal nanoparticles and their applications
Abstract
2.1 Introduction
2.2 Nanoparticles: types and synthesis approaches
2.3 Metallic nanoparticles and their classification
2.4 Waste-derived metal nanoparticles
2.5 Applications of metal nanoparticles
2.6 Conclusion and future paradigms
References
Chapter 3. Fundamental scope of nanomaterial synthesis from wastes
Abstract
3.1 Introduction
3.2 Waste as a synthesis of nanomaterial
3.3 Application of nanoparticles derived from waste
3.4 Waste as a synthesis of nanomaterials
3.5 Characterization and synthesis of the nanomaterials
3.6 Future directions and conclusions
References
Chapter 4. Anticipated challenges in the synthesis of different nanomaterials using biogenic waste
Abstract
4.1 Introduction
4.2 Sustainable development of the green synthesis of nanoparticles
4.3 Challenges of green approaches in nanoparticles synthesis
4.4 Challenges of synthesis of different nanomaterials using biogenic waste
4.5 Conclusion
References
Chapter 5. Domestic waste utilization in the synthesis of functional nanomaterial
Abstract
5.1 Introduction
5.2 Conclusion
References
Chapter 6. Panorama of microbial regimes toward nanomaterials’ synthesis
Abstract
6.1 Introduction
6.2 Application of nanomaterials in different fields
6.3 Pathway of biosynthesis of nanomaterials
6.4 Synthesis of various nanomaterials by using microorganisms
6.5 Genomic approach of biosynthesis of nanomaterials
6.6 Conclusion
Acknowledgment
References
Chapter 7. Sustainable valorization of food waste for the biogeneration of nanomaterials
Abstract
7.1 Introduction to food waste and nanomaterials
7.2 Elucidation of food waste
7.3 Synthesis of nanomaterials through different techniques
7.4 Types of nanomaterials synthesized from food waste
7.5 Applications and future perspective of nanomaterials in various areas
7.6 Conclusion
Acknowledgment
Disclosure statement
References
Chapter 8. Industrial wastes and their suitability for the synthesis of nanomaterials
Abstract
8.1 Introduction
8.2 Industrial waste
8.3 Advantages of synthesis of nanomaterial from industrial waste
8.4 Challenges
8.5 Future opportunities
8.6 Conclusion
References
Chapter 9. Scope to improve the synthesis of nanomaterial’s using industrial waste
Abstract
9.1 Introduction
9.2 Industrial wastes
9.3 Effect of industrial waste material on the environment
9.4 Synthesis of nanomaterials from industrial waste
9.5 Various types of nanomaterial synthesis
9.6 Mechanism of nanomaterial synthesis from industrial waste
9.7 Summary and future prospects
9.8 Conclusion
Acknowledgments
References
Chapter 10. Application and characterization of nonbiogenic synthesized nanomaterials
Abstract
10.1 Introduction
10.2 Impacts of nonbiogenic wastes
10.3 Nonbiogenic methods for the synthesis of nanomaterials
10.4 Synthesis of nanomaterials from nonbiogenic wastes
10.5 Characterization techniques of nonbiogenic synthesized nanomaterials
10.6 Application of nonbiogenic waste-derived nanomaterials
10.7 Summary and conclusion
References
Chapter 11. Nanomaterial synthesis using tire and plastic
Abstract
11.1 Introduction
11.2 Tire and plastic-based preparation of nanomaterials
11.3 Quartz tube
11.4 Autoclave
11.5 Crucible
11.6 Muffle furnace
11.7 Plastic and tire waste–based nanomaterials
11.8 Graphene-based nanomaterials
11.9 Metal and metal oxide nanoparticles
11.10 Applications of plastic and tire waste–based nanomaterials
11.11 Conclusion
References
Chapter 12. Emerging biowaste-derived surfaces to support redox-sensitive nanoparticles: applications in removal of synthetic dyes
Abstract
12.1 Introduction
12.2 Available dyes removal techniques
12.3 Redox-sensitive iron nanoparticles
12.4 Use of biowastes in designing and preserving reactivity of redox-sensitive nanoparticles
12.5 Application of surface-supported redox-sensitive iron nanocomposites in dyes removal and prevailing mechanisms
12.6 Conclusion: current challenges and future perspectives
References
Chapter 13. Nanomaterials synthesis from the industrial solid wastes
Abstract
13.1 Introduction
13.2 Industrial solid waste for the synthesis of nanomaterials
13.3 Synthesis of nanomaterials from solid waste
13.4 Sustainability consideration and future outlook
13.5 Conclusion
Acknowledgement
References
Chapter 14. Nanomaterials’ synthesis from the industrial solid wastes
Abstract
14.1 Introduction
14.2 Synthesis processes
14.3 Inorganic waste-based nanomaterials
14.4 Organic waste-based nanomaterials
14.5 Challenges and recommendations
14.6 Conclusion
References
Chapter 15. Green synthesis of nanomaterials from plant resources: its properties and applications
Abstract
15.1 Introduction
15.2 Plant-extracted bioactive molecules involved in the synthesis of nanomaterials
15.3 Plant resource for nanomaterials synthesis
15.4 Green synthesis methods for nanomaterials
15.5 Advantages of green synthesis methods over chemical synthesis for nanomaterials
15.6 Properties of nanomaterials synthesized from plant resources
15.7 Applications of green synthesis nanomaterials
15.8 Conclusion
References
Chapter 16. Nanotechnology for sustainable development and future: a review
Abstract
16.1 Introduction
16.2 Applications/uses of nanotechnology and its equipment
16.3 Conclusions and recommendations
Acknowledgments
Conflict of interest
References
Chapter 17. Utilization of biogenic waste as a valuable calcium resource in the hydrothermal synthesis of calcium-orthophosphate nanomaterial
Abstract
17.1 Introduction
17.2 Calcium orthophosphates phases
17.3 The demand for nanoparticle hydroxyapatite biomaterial powder on a global scale
17.4 Synthesis methods of hydroxyapatite based on biogenic waste
17.5 Various syntheses for producing hydroxyapatite powder
17.6 Hydrothermal synthesis of hydroxyapatite powders
17.7 Hydrothermal hydroxyapatite synthesis using biogenic waste shell sources
17.8 The current and future state of integrated calcium resource recovery for hydroxyapatite biomaterials
17.9 Conclusion
Acknowledgment
References
Chapter 18. A review of plant-derived metallic nanoparticles synthesized by biosynthesis: synthesis, characterization, and applications
Abstract
18.1 Introduction
18.2 Advantages of the plant extract-mediated synthesis of metallic nanoparticles
18.3 The role of plant extract in the synthesis of metallic nanoparticles
18.4 Various sources of plant extract employed in the synthesis of metallic nanoparticles
18.5 Effect of the plant extract on the synthesis and characteristics of metallic nanoparticles
18.6 Applications of plant extract-mediated synthesized metallic nanoparticles
18.7 Future prospects
18.8 Conclusion
Acknowledgment
References
Chapter 19. The intra- and extracellular mechanisms of microbially synthesized nanomaterials and their purification
Abstract
19.1 Introduction
19.2 Microbially synthesized nanomaterials
19.3 Purification methods of biosynthesized nanomaterials
19.4 Characterization of biosynthesized nanomaterials
19.5 Challenges and limitations
19.6 Conclusions and future outlook
References
Chapter 20. Fundamental scope of nanomaterial synthesis from wastes
Abstract
Abbreviations
20.1 Introduction
20.2 Recycling strategies of retrieved metals against the electronic waste
20.3 Synthetic approaches for the nanomaterials from electronic waste
20.4 Conclusion
References
Chapter 21. Application of nanomaterials synthesized using agriculture waste for wastewater treatment
Abstract
21.1 Introduction
21.2 Wastewater treatment using nanomaterials synthesized using agricultural waste
21.3 Mechanism and functions of nanocatalysts, nanoadsorbent, and nanodisinfectant
21.4 Summary, present status, conclusion, and future outlook
References
Chapter 22. Nanomaterial synthesis from the plant extract and tree part
Abstract
22.1 Introduction
22.2 Methods of synthesizing multifunctional nanomaterials from plant extract and other parts
22.3 Application of nanomaterials from plants
22.4 Conclusion and future prospective
References
Chapter 23. Recent advances in agriculture waste for nanomaterial production
Abstract
23.1 Introduction
23.2 Various forms of agricultural waste
23.3 Types of nanomaterial synthesized from agricultural wastes
23.4 Conclusion and future perspectives
References
Chapter 24. Nanomaterials’ synthesis from the fruit wastes
Abstract
24.1 Nanotechnology in pomology science
24.2 Types of nanomaterials
24.3 Synthesis of nanomaterials
24.4 Biosynthesis of nanomaterial
24.5 Some of the fruit wastes known for synthesis of nanomaterials
24.6 Types of nanomaterials produced using various fruit waste
24.7 Biosynthesis methods
24.8 Characterization of nanomaterials synthesized from fruit wastes
24.9 Multifunctional application of nanoparticles produced by green methods
24.10 Future aspects
24.11 Conclusions
References
Index

Abhishek Kumar Bhardwaj

Dr. Abhishek Kumar Bhardwaj is working as an Assistant Professor at Amity School of Life Sciences, Department of Environmental Science, Amity University, India. He obtained his PhD from the Central University of Allahabad, Prayagraj, India, in the field of environmental nanotechnology. He has also done Post-doctoral research at the Department of Environmental Science, VBS Purvanchal University, Jaunpur (India). Currently, He is actively involved in the teaching and guidance of undergraduate, MSc, and PhD students. Dr. Bhardwaj's research interests encompass a wide array of topics, including green synthesis of nanomaterials for water purification, bio-sensing, nano-based device fabrication, water treatment, diatom cultivation, mushroom cultivation, phytoremediation, and waste management. His contributions to the field are well-recognized, as he has published over 30 research papers in prestigious journals, including Elsevier, Springer, American Chemical Society, American Institute of Physics, MDPI, and Frontier, among others. Furthermore, Dr. Bhardwaj serves as a respected reviewer for esteemed journals such as Journals of Cleaner Production, Journals of Environmental Pollution, Bioresource Technology, Journals of Nanoparticle Research, Scientific Reports, and more. He has also edited two books in collaboration with Elsevier and Springer. His dedication to academia and research has made him a valuable asset to the scientific community and a significant influence in the field of environmental science and nanotechnology.

Affiliations and expertise

Assistant Professor, Amity School of Life Sciences, Department of Environmental Science, Amity University, Gwalior, Madhya Pradesh, India

Kuldip Dwivedi

Dr. Kuldip Dwivedi is a professor and the head of the Department of Environmental Science at Amity University Madhya Pradesh (AUMP) in Gwalior (India). In the year 2007, he received his Ph.D. on the topic "In vitro Screening and Biochemical Studies for Salt-Tolerance in Trifolium alexandrinum." He has a total of eight years of research experience and fifteen years of teaching experience. He has successfully mentored four students through the Ph.D. process. He is currently teaching and assisting graduation,postgraduate, and Ph.D students at Amity University in Gwalior in frontier areas of Environmental Science. Phytoremediation, ecological restoration, nanomaterials for environmental cleaning, biosensors for environment and agriculture, abiotic stress biology, environmental biotechnology, agro-ecological studies of crop plants, and micropropagation of important crop plants and trees are just a few of his research interests. He has over 30 research papers published in prestigious international and national journals. He's written two books for graduate students.

Affiliations and expertise

Department of Environmental Science, Amity University Madhya Pradesh (AUMP), India

Mika Sillanpaa

Mika Sillanpää is a Professor affiliated to the Department of Biological and Chemical Engineering at Aarhus University, as well as King Saud University, Saudi Arabia. He received his M.Sc. (Eng.) and D.Sc. (Eng.) from Aalto University, Finland. Prof. Sillanpää’s publications have been cited over 44,000 times (Google Scholar), and he has received numerous awards for research and innovation. Among these, he is the first Laureate of the Scientific Committee on the Problems of the Environment (SCOPE)’s Young Investigator Award. From 2017 to 2020, he has been listed as a Highly Cited Researcher by Thomson Reuters. In 2018, he was invited to become a Member of the Finnish Academy of Sciences and Letters and the Academy of Technical Sciences.

Affiliations and expertise

Professor, Department of Biological and Chemical Engineering, Aarhus University, Aarhus, Denmark

Arun Lal Srivastav

Arun Lal Srivastav is working as an Assistant Professor at Chitkara University, in India. He is currently involved in the teaching of Environmental Science, Environmental Engineering and Disaster Management to the undergraduate engineering students. His research interests include water treatment, river ecosystem, climate change, soil health maintenance, phytoremediation, and waste management. He has published around 50 research papers in various peer-reviewed, national and international journals, conferences, and books. He has also filed 12 patents.

Affiliations and expertise

Assistant Professor, Chitkara University, Himachal Pradesh, India