Energy from Waste
portes grátis
Energy from Waste
Production and Storage
Anh Nguyen, Tuan; Gupta, Ram K.
Taylor & Francis Ltd
03/2022
478
Dura
Inglês
9781032013596
15 a 20 dias
453
Descrição não disponível.
PART 1 Introduction. Chapter 1 Biowastes for Energy: An Introduction. PART 2 Municipal Waste for Energy. Chapter 2 Operational Tools and Techniques for Municipal Solid Waste Management. Chapter 3 Municipal Waste for Energy Production. Chapter 4 A Brief History of Energy Recovery from Municipal Solid Waste. Chapter 5 Materials and Energy from Waste Plastics: A Catalytic Approach. Chapter 6 Elucidating Sustainable Waste Management Approaches along with Waste-to-Energy Pathways: A Critical Review. Chapter 7 Biomass Downdraft Gasifier: State of the Art of Reactor Design. Chapter 8 Food-Based Waste for Energy. PART 3 Waste for Biochemicals and Bioenergy. Chapter 9 Biowastes for Ethanol Production. Chapter 10 Waste Feedstocks for Biodiesel Production. Chapter 11 Biowaste-Based Microbial Fuel Cells for Bioelectricity Generation. Chapter 12 Biowaste-Based Microbial Fuel Cells. Chapter 13 Recent Development in Microbial Fuel Cells Using Biowaste. Chapter 14 Waste-Derived Carbon Materials for Hydrogen Storage. Chapter 15 Organic Waste for Hydrogen Production. Chapter 16 Recycling E-Waste for Hydrogen Energy Production and Replacement as Building Construction Materials. PART 4 Waste for Advanced Energy Devices. Chapter 17 Biowaste-Derived Carbon for Solar Cells. Chapter 18 Biowastes for Metal-Ion Batteries. Chapter 19 NaFePO4 Regenerated from Failed Commercial Li-Ion Batteries for Na-Ion Battery Applications. Chapter 20 Polymeric Wastes for Metal-Ion Batteries. Chapter 21 Biowaste-Derived Components for Zn-Air Battery. Chapter 22 Recycling of Wastes Generated in Automobile Metal-Air Batteries. Chapter 23 Biowastes for Metal-Sulfur Batteries. Chapter 24 High-Performance Supercapacitors Based on Biowastes for Sustainable Future. Chapter 25 Hybrid Biowaste Materials for Supercapacitors. Chapter 26 Polymeric Wastes for Supercapacitors. Chapter 27 Carbon Nanostructures Derived from Polymeric Wastes for Supercapacitors. Chapter 28 Supercapacitors Based on Waste Generated in Automobiles. Chapter 29 Halogenated Polymeric Wastes for Green Functional Carbon Materials. Chapter 30 Waste Mechanical Energy Harvesting from Vehicles by Smart Materials
Este título pertence ao(s) assunto(s) indicados(s). Para ver outros títulos clique no assunto desejado.
valorization;zero waste fuel cells;metal-air batteries;metal-sulfur batteries;Supercapacitors;metal-ion batteries;ethanol;automobile waste;biodiesel hydrogen production;MFCs;Energy Density;Electrochemical Performance;Carbon Materials;Hydrogen Production;MECs;Energy Recovery;Energy Sources;Electrode Materials;Electric Vehicles;American Chemical Society;Porous Carbon;Metal Air Batteries;HTC;Moisture Content;HPC;Polymer Waste;Ad;Single Chamber MFC;Mesoporous Carbon;Heteroatom Doping;AC;MSW Management;Air Cathodes;Lithium Ion Batteries
PART 1 Introduction. Chapter 1 Biowastes for Energy: An Introduction. PART 2 Municipal Waste for Energy. Chapter 2 Operational Tools and Techniques for Municipal Solid Waste Management. Chapter 3 Municipal Waste for Energy Production. Chapter 4 A Brief History of Energy Recovery from Municipal Solid Waste. Chapter 5 Materials and Energy from Waste Plastics: A Catalytic Approach. Chapter 6 Elucidating Sustainable Waste Management Approaches along with Waste-to-Energy Pathways: A Critical Review. Chapter 7 Biomass Downdraft Gasifier: State of the Art of Reactor Design. Chapter 8 Food-Based Waste for Energy. PART 3 Waste for Biochemicals and Bioenergy. Chapter 9 Biowastes for Ethanol Production. Chapter 10 Waste Feedstocks for Biodiesel Production. Chapter 11 Biowaste-Based Microbial Fuel Cells for Bioelectricity Generation. Chapter 12 Biowaste-Based Microbial Fuel Cells. Chapter 13 Recent Development in Microbial Fuel Cells Using Biowaste. Chapter 14 Waste-Derived Carbon Materials for Hydrogen Storage. Chapter 15 Organic Waste for Hydrogen Production. Chapter 16 Recycling E-Waste for Hydrogen Energy Production and Replacement as Building Construction Materials. PART 4 Waste for Advanced Energy Devices. Chapter 17 Biowaste-Derived Carbon for Solar Cells. Chapter 18 Biowastes for Metal-Ion Batteries. Chapter 19 NaFePO4 Regenerated from Failed Commercial Li-Ion Batteries for Na-Ion Battery Applications. Chapter 20 Polymeric Wastes for Metal-Ion Batteries. Chapter 21 Biowaste-Derived Components for Zn-Air Battery. Chapter 22 Recycling of Wastes Generated in Automobile Metal-Air Batteries. Chapter 23 Biowastes for Metal-Sulfur Batteries. Chapter 24 High-Performance Supercapacitors Based on Biowastes for Sustainable Future. Chapter 25 Hybrid Biowaste Materials for Supercapacitors. Chapter 26 Polymeric Wastes for Supercapacitors. Chapter 27 Carbon Nanostructures Derived from Polymeric Wastes for Supercapacitors. Chapter 28 Supercapacitors Based on Waste Generated in Automobiles. Chapter 29 Halogenated Polymeric Wastes for Green Functional Carbon Materials. Chapter 30 Waste Mechanical Energy Harvesting from Vehicles by Smart Materials
Este título pertence ao(s) assunto(s) indicados(s). Para ver outros títulos clique no assunto desejado.
valorization;zero waste fuel cells;metal-air batteries;metal-sulfur batteries;Supercapacitors;metal-ion batteries;ethanol;automobile waste;biodiesel hydrogen production;MFCs;Energy Density;Electrochemical Performance;Carbon Materials;Hydrogen Production;MECs;Energy Recovery;Energy Sources;Electrode Materials;Electric Vehicles;American Chemical Society;Porous Carbon;Metal Air Batteries;HTC;Moisture Content;HPC;Polymer Waste;Ad;Single Chamber MFC;Mesoporous Carbon;Heteroatom Doping;AC;MSW Management;Air Cathodes;Lithium Ion Batteries
