Sustainable biotechnology-enzymatic resources of renewable energy
Contents: Intro; Foreword; Contents; About the Editors; 1 Introduction; References; 2 Role ofSystematic Biology inBiorefining ofLignocellulosic Residues forBiofuels andChemicals Production; 2.1 Introduction; 2.2 Concept ofBiorefineries; 2.3 Biofuel asRenewable Energy Source; 2.4 Lignocellulosic Biom...
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Life sciences; Biomass energy; TECHNOLOGY & ENGINEERING
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Life sciences; Biomass energy; TECHNOLOGY & ENGINEERING -- Chemical & Biochemical; Biomass energy; Science -- Energy; Science -- Biotechnology; Alternative & renewable energy sources & technology; Biotechnology; Microbiology; Renewable energy sources; Biotechnology; Science -- Life Sciences -- Biology -- Microbiology; Microbiology (non-medical); Electronic books |
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Life sciences; Biomass energy; TECHNOLOGY & ENGINEERING -- Chemical & Biochemical; Biomass energy; Science -- Energy; Science -- Biotechnology; Alternative & renewable energy sources & technology; Biotechnology; Microbiology; Renewable energy sources; Biotechnology; Science -- Life Sciences -- Biology -- Microbiology; Microbiology (non-medical); Electronic books Om V. Singh, Anuj K. Chandel, editors Sustainable biotechnology-enzymatic resources of renewable energy |
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Contents: Intro; Foreword; Contents; About the Editors; 1 Introduction; References; 2 Role ofSystematic Biology inBiorefining ofLignocellulosic Residues forBiofuels andChemicals Production; 2.1 Introduction; 2.2 Concept ofBiorefineries; 2.3 Biofuel asRenewable Energy Source; 2.4 Lignocellulosic Biomass forBioethanol Production; 2.5 Pretreatment oftheLignocellulosic Biomass; 2.5.1 Physical Pretreatment; 2.5.2 Chemical Pretreatment; 2.5.3 Biological Pretreatment; 2.6 Enzymatic Saccharification ofPretreated Lignocellulosic Biomass; 2.7 Ethanol Fermentation; 2.8 Biohydrogen asBiofuel.
Contents: 2.9 Microalgae forBiohydrogen Production2.10 Biobutanol asBiofuel; 2.11 Strategical Improvements forBiobutanol Production; 2.12 Lignocellulosic Biomass asSource ofPrebiotics; 2.12.1 Xylooligosaccharides asPrebiotics; 2.13 Delignification ofBiomass forXOS Production; 2.14 Xylan Extraction fromLignocellulosic Biomass; 2.14.1 Alkaline Extraction; 2.14.2 Acid Extraction; 2.14.3 Autohydrolysis; 2.15 Enzymatic Production ofXylooligosaccharides; 2.16 Strategical Improvements forProduction ofXOS; 2.17 Lignocellulosic Biomass forPolyhydroxybutyrate (PHB) Production.
Contents: 2.18 Bacillus spp. forPHB Production2.19 Strategies forPHB Production; 2.19.1 Process Optimization forPHB Production; 2.19.2 Application ofGenetic Engineering Tools; 2.19.3 Pretreatment ofBiomass; 2.19.4 Structural Modifications ofPHB; 2.20 Lignocellulose Biomass forProduction ofIndustrial Enzymes; 2.21 Conclusion; 2.22 Future Prospects; References; 3 Biotechnological Advances inLignocellulosic Ethanol Production; 3.1 Introduction; 3.2 Bioethanol Production: Statistics andGlobal Overview; 3.3 Potential Feedstock, Biomass Composition andSurplus Availability.
Contents: 3.4 Feedstock Processing toGenerate Sugars asBuilding Block3.5 Types ofPretreatment Methods; 3.5.1 Physical Pretreatment Approaches; 3.5.2 Chemical Pretreatment Methods; 3.5.3 Physicochemical Pretreatment Methods; 3.6 Biological Pretreatment Methods; 3.7 Biotechnological Advancements; 3.7.1 Microbial Production ofCellulases andEnzymatic Hydrolysis ofPretreated Substrates; 3.7.2 Hydrolysis ofPretreated Biomass; 3.8 Biotechnological Advancements; 3.8.1 Strategies Used toImprove Fungal Enzyme Production; 3.8.2 Mutagenesis; 3.8.3 Co-cultivation; 3.8.4 Metabolic Engineering.
Contents: 3.8.5 Heterologous Expression3.8.6 Immobilization; 3.9 Bioethanol Recovery fromFermented Broth; 3.10 Conclusion; References; 4 Sustainable Production ofBiofuels fromWeedy Biomass andOther Unconventional Lignocellulose Wastes; 4.1 Introduction; 4.2 Technological Option andLimitations ofBiofuel Production; 4.3 Lignocellulosic Biomass Composition ofWeedy Biomass; 4.3.1 Cellulose (C6H10O5)n; 4.3.2 Hemicellulose (C5H8O4)n; 4.3.3 Lignin [C9H10O3(OCH3)]n; 4.4 Available Bioresources forSustainable Biofuel Production; 4.4.1 Agricultural byProducts; 4.5 Weedy Lignocellulosic Biomass. |
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Om V. Singh, Anuj K. Chandel, editors |
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Om V. Singh, Anuj K. Chandel, editors |
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Om V. Singh, Anuj K. Chandel, editors |
title |
Sustainable biotechnology-enzymatic resources of renewable energy |
title_short |
Sustainable biotechnology-enzymatic resources of renewable energy |
title_full |
Sustainable biotechnology-enzymatic resources of renewable energy |
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Sustainable biotechnology-enzymatic resources of renewable energy |
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Sustainable biotechnology-enzymatic resources of renewable energy |
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sustainable biotechnology-enzymatic resources of renewable energy |
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2020 |
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http://dspace.uniten.edu.my/jspui/handle/123456789/13543 |
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my.uniten.dspace-135432020-03-04T03:16:46Z Sustainable biotechnology-enzymatic resources of renewable energy Om V. Singh, Anuj K. Chandel, editors Life sciences; Biomass energy; TECHNOLOGY & ENGINEERING -- Chemical & Biochemical; Biomass energy; Science -- Energy; Science -- Biotechnology; Alternative & renewable energy sources & technology; Biotechnology; Microbiology; Renewable energy sources; Biotechnology; Science -- Life Sciences -- Biology -- Microbiology; Microbiology (non-medical); Electronic books Contents: Intro; Foreword; Contents; About the Editors; 1 Introduction; References; 2 Role ofSystematic Biology inBiorefining ofLignocellulosic Residues forBiofuels andChemicals Production; 2.1 Introduction; 2.2 Concept ofBiorefineries; 2.3 Biofuel asRenewable Energy Source; 2.4 Lignocellulosic Biomass forBioethanol Production; 2.5 Pretreatment oftheLignocellulosic Biomass; 2.5.1 Physical Pretreatment; 2.5.2 Chemical Pretreatment; 2.5.3 Biological Pretreatment; 2.6 Enzymatic Saccharification ofPretreated Lignocellulosic Biomass; 2.7 Ethanol Fermentation; 2.8 Biohydrogen asBiofuel. Contents: 2.9 Microalgae forBiohydrogen Production2.10 Biobutanol asBiofuel; 2.11 Strategical Improvements forBiobutanol Production; 2.12 Lignocellulosic Biomass asSource ofPrebiotics; 2.12.1 Xylooligosaccharides asPrebiotics; 2.13 Delignification ofBiomass forXOS Production; 2.14 Xylan Extraction fromLignocellulosic Biomass; 2.14.1 Alkaline Extraction; 2.14.2 Acid Extraction; 2.14.3 Autohydrolysis; 2.15 Enzymatic Production ofXylooligosaccharides; 2.16 Strategical Improvements forProduction ofXOS; 2.17 Lignocellulosic Biomass forPolyhydroxybutyrate (PHB) Production. Contents: 2.18 Bacillus spp. forPHB Production2.19 Strategies forPHB Production; 2.19.1 Process Optimization forPHB Production; 2.19.2 Application ofGenetic Engineering Tools; 2.19.3 Pretreatment ofBiomass; 2.19.4 Structural Modifications ofPHB; 2.20 Lignocellulose Biomass forProduction ofIndustrial Enzymes; 2.21 Conclusion; 2.22 Future Prospects; References; 3 Biotechnological Advances inLignocellulosic Ethanol Production; 3.1 Introduction; 3.2 Bioethanol Production: Statistics andGlobal Overview; 3.3 Potential Feedstock, Biomass Composition andSurplus Availability. Contents: 3.4 Feedstock Processing toGenerate Sugars asBuilding Block3.5 Types ofPretreatment Methods; 3.5.1 Physical Pretreatment Approaches; 3.5.2 Chemical Pretreatment Methods; 3.5.3 Physicochemical Pretreatment Methods; 3.6 Biological Pretreatment Methods; 3.7 Biotechnological Advancements; 3.7.1 Microbial Production ofCellulases andEnzymatic Hydrolysis ofPretreated Substrates; 3.7.2 Hydrolysis ofPretreated Biomass; 3.8 Biotechnological Advancements; 3.8.1 Strategies Used toImprove Fungal Enzyme Production; 3.8.2 Mutagenesis; 3.8.3 Co-cultivation; 3.8.4 Metabolic Engineering. Contents: 3.8.5 Heterologous Expression3.8.6 Immobilization; 3.9 Bioethanol Recovery fromFermented Broth; 3.10 Conclusion; References; 4 Sustainable Production ofBiofuels fromWeedy Biomass andOther Unconventional Lignocellulose Wastes; 4.1 Introduction; 4.2 Technological Option andLimitations ofBiofuel Production; 4.3 Lignocellulosic Biomass Composition ofWeedy Biomass; 4.3.1 Cellulose (C6H10O5)n; 4.3.2 Hemicellulose (C5H8O4)n; 4.3.3 Lignin [C9H10O3(OCH3)]n; 4.4 Available Bioresources forSustainable Biofuel Production; 4.4.1 Agricultural byProducts; 4.5 Weedy Lignocellulosic Biomass. Even with greater efforts from developed and developing nations, it seems unlikely to resolve the issues involving with atmospheric CO2 levels. The effects of this issue are affecting the climate, the adoption of global conservation measure, and the stabilization offossil fuel prices. It is still a certainty that global oil and gas supplies will be largely depleted in a matter of decades. However, nature provides abundant renewable resources that can be used to replace fossil fuels, if not completely but at least to some extent. However, major issues remain at the forefront such as cost, technology readiness levels, and compatibility with existing distribution networks. In current scenario, the cellulosic fuel remains unsuccessful to reduce societal independence from fossil fuel. There is a need to continue to bridge the technology gap and focus on the critical aspects of lignocellulosic biomolecules conversion. In addition, the value-added products of industrial significance are among top priority during bioconversion to liquid fuels. Therefore, the respective molecular mechanisms regulating the bioconversion of liquid fuel may remain to be discovered so that biofuel could become a reality at a reasonable cost. Commercialisation of biofuels and biochemicals is a great challenge, however not impossible to met with the demands of sustainable energy. This book provides the key aspects of molecular mechanism of liquid fuel and value-added products of industrial significance. Uniquely, the editors focused on technological updates on biomass processing, system biology, microbial fermentation, catalysis, regeneration, and monitoring of renewable energy and recovery process. This book also offers facts of techno-economic analysis, climate change, and geopolitical interpretation of bioenergy aspects. 2020-03-04T03:16:46Z 2020-03-04T03:16:46Z 2018 Book http://dspace.uniten.edu.my/jspui/handle/123456789/13543 en Springer |
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