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Green nanomaterials : from bioinspired synthesis to sustainable manufacturing of inorganic nanomaterials /

This book covers emerging bioinspired green methods for preparing inorganic nanomaterials. The book starts with an introduction to the principles of green chemistry and engineering, and highlights the special properties that nanomaterials possess, their applications and ways to characterise them. It...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autores principales: Patwardhan, Siddharth V. (Autor), Staniland, Sarah S. (Autor)
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Bristol [England] (Temple Circus, Temple Way, Bristol BS1 6HG, UK) : IOP Publishing, [2020]
Colección:IOP ebooks. 2020 collection.
Temas:
Acceso en línea:Texto completo

MARC

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100 1 |a Patwardhan, Siddharth V.,  |e author. 
245 1 0 |a Green nanomaterials :  |b from bioinspired synthesis to sustainable manufacturing of inorganic nanomaterials /  |c Siddharth V. Patwardhan, Sarah S. Staniland. 
246 3 0 |a From bioinspired synthesis to sustainable manufacturing of inorganic nanomaterials. 
264 1 |a Bristol [England] (Temple Circus, Temple Way, Bristol BS1 6HG, UK) :  |b IOP Publishing,  |c [2020] 
300 |a 1 online resource (various pagings) :  |b illustrations (some color). 
336 |a text  |2 rdacontent 
337 |a electronic  |2 isbdmedia 
338 |a online resource  |2 rdacarrier 
490 1 |a IOP ebooks. [2020 collection] 
500 |a "Version: 20191201"--Title page verso. 
504 |a Includes bibliographical references. 
505 0 |a section I. Green chemistry principles. 1. Green chemistry and engineering -- 1.1. Principles of green chemistry and engineering -- 1.2. Ways to improve sustainability -- 1.3. Green chemistry and nanomaterials 
505 8 |a section II. Nanomaterials. 2. Nanomaterials : what are they and why do we want them? -- 2.1. Fundamentals of the nanoscale -- 2.2. Tangible and historical examples of nanomaterials -- 2.3. Special properties offered by the nanoscale -- 2.4. Applications -- 2.5. Nanomaterial biocompatibility and toxicity -- 2.6. Summary : key lessons from nanomaterials, nanoproperties and applications 
505 8 |a 3. Characterisation of nanomaterials -- 3.1. Introduction -- 3.2. Microscopy -- 3.3. Spectroscopy applied to nanomaterials -- 3.4. Diffraction and scattering techniques -- 3.5. Porosimetry -- 3.6. Summary : key lessons for characterisation of nanomaterials 
505 8 |a 4. Conventional methods to prepare nanomaterials -- 4.1. Top-down and bottom-up methods -- 4.2. Top-down methods -- 4.3. Bottom-up methods -- 4.4. Nucleation and growth theory -- 4.5. Conventional bottom-up methods -- 4.6. Emerging bottom-up methods -- 4.7. Summary : key lessons about conventional routes to nanomaterials 
505 8 |a section III. From biominerals to green nanomaterials. 5. Green chemistry for nanomaterials -- 5.1. Sustainability of nanomaterials production -- 5.2. Reasons behind unsustainability -- 5.3. Evaluation of sustainability for selected methods -- 5.4. Adopting green chemistry for nanomaterials -- 5.5. Biological and biochemical terminology and methods -- 5.6. Summary : key lessons about sustainability nanomaterials production 
505 8 |a 6. Biomineralisation : how Nature makes nanomaterials -- 6.1. Introduction -- 6.2. Properties and function of biomineral types -- 6.3. Mineral formation controlling strategies in biomineralisation -- 6.4. Roles and types of organic biological components required for biomineralisation -- 6.5. Summary : key lessons from biomineralisation for the green synthesis of nanomaterials 
505 8 |a 7. Bioinspired 'green' synthesis of nanomaterials -- 7.1. From biological to bioinspired synthesis -- 7.2. Mechanistic understanding -- 7.3. An illustration of exploiting the knowledge of nano-bio interactions -- 7.4. Additives as the mimics of biomineral forming biomolecules -- 7.5. Compartmentalisation, templating and patterning -- 7.6. Scalability of bioinspired syntheses -- 7.7. Summary : key lessons about the journey towards bioinspired synthesis 
505 8 |a section IV. Case studies. 8. Case study 1 : magnetite nanoparticles -- 8.1. Magnetite biomineralisation in magnetotactic bacteria -- 8.2. Magnetosome use in applications : advantages and drawbacks -- 8.3. Biomolecules and components controlling magnetosome formation -- 8.4. Biokleptic use of Mms proteins for magnetite synthesis in vitro -- 8.5. Understanding Mms proteins in vitro -- 8.6. Development and design of additives : emergence of bioinspired magnetite nanoparticle synthesis -- 8.7. Summary : key learning, and the future (towards manufacture) 
505 8 |a 9. Case study 2 : silica -- 9.1. Biosilica occurrence and formation -- 9.2. Biomolecules controlling biosilica formation -- 9.3. Learning from biological silica synthesis : in vitro investigation of bioextracts -- 9.4. Emergence of bioinspired synthesis using synthetic 'additives' -- 9.5. Benefits of bioinspired synthesis -- 9.6. From lab to market -- 9.7. Summary : key learning, summary and the future. 
520 3 |a This book covers emerging bioinspired green methods for preparing inorganic nanomaterials. The book starts with an introduction to the principles of green chemistry and engineering, and highlights the special properties that nanomaterials possess, their applications and ways to characterise them. It describes conventional methods of synthesising and manufacturing inorganic nanomaterials, and introduces biological and biomimetic/bioinspired synthetic methods as a solution to precisely control nanomaterials and design sustainable manufacturing routes. The book elaborates on various mechanisms and examples of green nanomaterials, including the role of organic matrix and natural self-assembly, and advantages and opportunities with green nanomaterials. Two case studies of magnetic and silica materials are provided for advanced readers. The book is an insightful reference text for researchers focusing on synthetic biology and nanomaterials. It is an essential title for postgraduates and final-year undergraduates studying advanced materials, sustainable engineering or environmental chemistry. 
530 |a Also available in print. 
538 |a Mode of access: World Wide Web. 
538 |a System requirements: Adobe Acrobat Reader, EPUB reader, or Kindle reader. 
545 |a Siddharth Patwardhan is a Professor of Sustainable Chemical and Materials Engineering at the University of Sheffield. He leads the Green Nanomaterials Research Group (svplab.com) with a vision to develop sustainable routes to functional nanomaterials. The group focusses on the discovery of bioinspired nanomaterials, assessing their scalability and developing manufacturing technologies for energy, environmental, biomedical and engineering applications. Sarah Staniland is a Reader of Bionano-Materials in the Department of Chemistry at the University of Sheffield. She leads the Bionanomagnetic Research Group, which studies the biomimetic synthesis of magnetic nanomaterials and is particularly inspired by the production of magnetite nanoparticles within magnetic bacteria. 
588 0 |a Title from PDF title page (viewed on January 6, 2020). 
650 0 |a Nanostructured materials  |x Environmental aspects. 
650 0 |a Sustainable development. 
650 7 |a Nanotechnology.  |2 bicssc 
650 7 |a SCIENCE / Nanoscience.  |2 bisacsh 
700 1 |a Staniland, Sarah S.,  |e author. 
710 2 |a Institute of Physics (Great Britain),  |e publisher. 
776 0 8 |i Print version:  |z 9780750312226  |z 9780750318365 
830 0 |a IOP ebooks.  |p 2020 collection. 
856 4 0 |u https://iopscience.uam.elogim.com/book/978-0-7503-1221-9  |z Texto completo