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LEADER 00000cam a22005057i 4500
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006 m o d
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008 230814t20232023nju o 000 0 eng d
020 9781119785699|qelectronic book
020 1119785693|qelectronic book
020 9781119785712|qelectronic book
020 1119785715|qelectronic book
020 |qhardcover
020 |qhardcover
029 1 AU@|b000075037858
035 (OCoLC)1393344852
037 9781119785675|bO'Reilly Media
040 YDX|beng|erda|cYDX|dYDX|dDG1|dOCLCO|dORMDA|dSFB
049 INap
082 04 333.79/4
082 04 333.79/4|223/eng/20230906
099 eBook O'Reilly for Public Libraries
245 00 Renewable energy innovations :|bbiofuels, solar, and other
technologies /|cedited by Alok Patel and Amit Kumar
Sharma.|h[O'Reilly electronic resource]
264 1 Hoboken, NJ :|bJohn Wiley & Sons, Inc. ;|aBeverly, MA :
|bScrivener Publishing LLC,|c2023.
264 4 |c©2023
300 1 online resource
336 text|btxt|2rdacontent
337 computer|bc|2rdamedia
338 online resource|bcr|2rdacarrier
505 0 Intro -- Table of Contents -- Series Page -- Title Page --
Copyright Page -- 1 Microbial Fuel Cells -- A Sustainable
Approach to Utilize Industrial Effluents for Electricity
Generation -- Abbreviation -- 1.1 Introduction -- 1.2
History of Microbial Fuel Cell -- 1.3 Principle of
Microbial Fuel Cell -- 1.4 Material Used in MFC System --
1.5 Electrogenic Microorganisms -- 1.6 Electron Transport
Mechanism in MFCs -- 1.7 Configuration of MFC -- 1.8
Applications of Microbial Fuel Cell -- 1.9 Future
Perspectives -- 1.10 Conclusion -- References -- 2
Nanotechnologies in the Renewable Energy Sector -- 2.1
Introduction -- 2.2 Fundamentals of Renewable Energy
Sources -- 2.3 Storage of Energy in Electrical Devices --
2.4 Nanotechnology in Energy Storage Devices -- 2.5
Nanomaterials for Rechargeable Batteries -- 2.6
Nanomaterials in Fuel Cells -- 2.7 Conclusion -- 2.8
Future Scope -- References -- 3 Sustainable Approach in
Utilizing Bioenergy Commonly for Industrial Zones by
Limiting Overall Emission Footprint -- 3.1 Introduction --
3.2 Co-Firing Plants in Small- and Medium-Scale Industries
-- 3.3 Impact of Usage of Biogas for Steam Generation --
3.4 Case Scenarios for Promoting Industrial Uptake -- 3.5
Conclusion -- Acknowledgment -- References -- 4 Recycling
of Plastic Waste into Transportation Fuels and Value-Added
Products -- 4.1 Introduction -- 4.2 Plastic Waste: A
Global Challenge -- 4.3 Future Projection of the Waste
Plastic -- 4.4 Plastic Waste Effect on Environment and
Ecology -- 4.5 Plastic Waste Management -- 4.6 Parameters
Affect the Pyrolysis Process -- 4.7 Value-Added Products
from Plastic Waste Pyrolysis -- 4.8 Application in
Transportation Sector -- 4.9 Conclusion -- References -- 5
An Outlook on Oxygenated Fuel for Transportation -- 5.1
Introduction -- 5.2 Oxygenated Fuel -- References.
505 8 6 Greenhouse Gas (GHG) Emissions and Its Mitigation
Technology in Transportation Sector -- 6.1 Introduction --
6.2 Mitigation Technologies -- 6.3 Conclusion --
References -- 7 Advanced Techniques for Bio-Methanol
Production -- 7.1 Introduction -- 7.2 Scope of Biofuel --
7.3 Types of Biofuels -- 7.4 Why Biomethanol -- 7.5
Methanol Properties -- 7.6 Source of Bio-Methanol -- 7.7
Production of Methanol -- 7.8 Gasification -- 7.9
Pyrolysis -- 7.10 Liquefaction -- 7.11 Syngas to Methanol
-- 7.12 Biomethanol from MSW -- 7.13 Energy Efficiency of
a Process -- 7.14 Biological Conversion of Methanol --
7.15 Anaerobic Digestion -- 7.16 Methanotrophic Bacteria -
- 7.17 Production of Methanol from Methanotrophic Bacteria
(Methanotrophs) -- 7.18 Large-Scale Production of Methanol
from Waste Biomass -- 7.19 Challenges Associated with
Methanol Production Using Methanotrophic Bacteria at the
Industrial Level -- 7.20 Role of Ammonia-Oxidizing
Bacteria (AOB) -- 7.21 Future Prospective and Conclusion -
- References -- 8 Biodiesel Production: Advance Techniques
and Future Prospective -- 8.1 Introduction -- 8.2
Biodiesel and Its Properties -- 8.3 Synthesis of Biodiesel
-- 8.4 Modern Methods for the Development of Prospects --
8.5 Future Prospects and Policies -- 8.6 Conclusions --
References -- 9 Biomass to Biofuel: Biomass Sources,
Pretreatment Methods and Production Strategies -- 9.1
Introduction -- 9.2 Biomass Sources in India -- 9.3
Lignocellulosic Biomass -- 9.4 Biomass Pretreatment
Methods -- 9.5 Biomass to Biofuel Conversion Technologies
-- 9.6 Types of Biofuel -- 9.7 Conclusion -- References --
10 Opportunity and Challenges in Biofuel Productions
through Solar Thermal Technologies -- 10.1 Introduction --
10.2 Solar Pyrolysis of Biomass Feedstocks -- 10.3
Production of Bio-Oil by Solar Pyrolysis -- 10.4
Conclusions -- References.
505 8 11 Algae Biofuels: A Promising Fuel of the Transport
Sector -- 11.1 Introduction -- 11.2 Biofuels in the
Transport Sector -- 11.3 Modes of Biofuels in Practice --
11.4 Algae Biofuel -- A Promising Energy Source -- 11.5
Microalgae Growth Conditions -- 11.6 Harvesting of Algae -
- 11.7 Biofuel Extraction Techniques from Microalgae --
11.8 Algae Biofuel as a Transport Fuel -- 11.9 Conclusion
-- References -- 12 A Review of Chemical and Physical
Parameters of Biodiesel vs. Diesel: Their Environmental
and Economic Impact -- 12.1 Introduction -- 12.2
Historical Background -- 12.3 Current Status of Biodiesel
-- 12.4 Sources of Biodiesel -- 12.5 Advantages of
Biodiesel Over Diesel -- 12.6 Biodiesel as Safer and
Cleaner Fuel -- 12.7 Major Negative Aspects to Use of
Biodiesel -- 12.8 Chemical and Physical Properties of
Biodiesel -- 12.9 Biodiesel Applications -- 12.10
Conclusion and Future Prospective -- Acknowledgments --
References -- 13 An Indian Viewpoint on Promoting Hydrogen
-Powered Vehicles: Focussing on the Scope of Fuel Cells --
List of Abbreviations -- 13.1 Introduction -- 13.2 Can
Hydrogen Be the Way Forward? -- 13.3 The Inception of Fuel
Cells (FCs) and PEMFCs in Particular -- 13.4 FCEVs v/s
Existing Automobile Infrastructure in India -- 13.5 The
Green Policy Push for Hydrogen and Associated Technologies
in India -- 13.6 Pervasive Challenges of PEMFC Technology
-- 13.7 Conclusion and Recommendations -- Acknowledgments
-- References -- 14 Microalgae as Source of Bioenergy --
14.1 Introduction -- 14.2 Microalgae Bioenergy Production
Options -- 14.3 Conclusions -- Acknowledgement --
References -- 15 Hazards and Environmental Issues in
Biodiesel Industry -- 15.1 Introduction -- 15.2 Life Cycle
Analysis of Biodiesel -- 15.3 Life Cycle Analysis of
Biodiesel -- 15.4 Future Risk and Opportunities -- 15.5
Future Risk and Opportunities -- 15.6 Conclusion.
520 RENEWABLE ENERGY INNOVATIONS This critical text, designed
for microbiologists, biotechnologists, entrepreneurs,
process engineers, chemical engineers, electrical
engineers, physicists, and environmentalists, assesses the
current knowledge about lab-scale and large-scale
production of renewable and sustainable fuels, chemicals,
and materials. Global warming is having a huge impact on
the world's ecosystem. Glaciers have shrunk, ice on rivers
and lakes is breaking up early, and plant and animal
ranges have relocated. On a worldwide scale, the threat
posed by climate change and pollution is obvious. A green
and sustainable future necessitates using renewable
resources to produce fuels, chemicals, and materials. This
book investigates diverse bioprocesses that are crucial to
everyday life, including the key concerns regarding the
generation of biofuels, energy, and food securities, along
with waste management. Commercial interest in
biotechnological processes has risen to produce
pharmaceuticals, health supplements, foodstuffs, biofuels,
and chemicals using a biocatalyst such as enzymes,
microorganisms, plant cells, or animal cells in a
bioreactor. The sustainability of renewable biomass,
replacement of depleted fossil fuels, and the mitigation
of greenhouse gas emissions from the existing chemical and
oil industries are the key benefits of switching to
bioproducts. This book discusses bioprocessing to produce
biofuels, biobased chemicals, bioproducts, and biomass
biorefinery processes. This involves designing novel
pretreatment and fractionation technologies for
lignocellulose biomass into cellulose, hemicellulose, and
lignin and the conversion of these streams into biofuels
and biobased chemicals via biochemical and thermochemical
routes. This book also covers the advancement of
oleaginous microorganisms for biofuels and nutraceutical,
biological wastewater treatment. Written and edited by
authors from leading biotechnology research groups from
across the world, this exciting new volume covers all of
these technologies, including the basic concepts and the
problems and solutions involved with the practical
applications in the real world. Whether for the veteran
engineer or scientist, student, manager, or another
technician working in the field, this volume is essential
for any library.
588 Description based on online resource; title from digital
title page (viewed on September 06, 2023).
590 O'Reilly|bO'Reilly Online Learning: Academic/Public
Library Edition
650 0 Renewable energy sources.
650 6 Énergies renouvelables.
700 1 Patel, Alok,|eeditor.
700 1 Sharma, Amit Kumar,|eeditor.
776 08 |iPrint version:|z1119785677|z9781119785675
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