Comprehensive reference summarizing different technologies for application-oriented biochar production from waste biomass resources in rural areas Waste-derived Biochar for Sustainable Rural Revitalization summarizes recent research developments, introduces state-of-the-art knowledge, incorporates case studies, offers scientific insights, highlights current challenges, and shows the way forward for biochar technologies as a novel, cost-effective, and environmentally friendly solution for sustainable rural revitalization. This book succinctly summarizes different technologies for…mehr
Comprehensive reference summarizing different technologies for application-oriented biochar production from waste biomass resources in rural areas Waste-derived Biochar for Sustainable Rural Revitalization summarizes recent research developments, introduces state-of-the-art knowledge, incorporates case studies, offers scientific insights, highlights current challenges, and shows the way forward for biochar technologies as a novel, cost-effective, and environmentally friendly solution for sustainable rural revitalization. This book succinctly summarizes different technologies for application-oriented biochar production from waste biomass resources (e.g., crop residues, pruning of fruit trees, animal waste, food waste, and domestic sludge) in rural areas, with an emphasis on tailored selection of pyrolytic and pre/post-treatment conditions. Readers will find information on renewable biofuels, clean compost conditioner, organic seeding substrate, slow-release fertilizers, green pesticides, targeting plant disease suppressors, farmland soil conditioner/amendment, adsorbent/catalyst for agriculture wastewater treatment, farmland carbon sequestration, and low-carbon construction materials. This book also evaluates these technologies through Technical and Economic Analysis (TEA) and Environmental, Social, and Governance (ESG) frameworks and discusses potential environmental risks. Written by a team of highly qualified authors, Waste-derived Biochar for Sustainable Rural Revitalization explores sample topics including: * Slow, fast, microwave, and flash pyrolysis, physical and chemical modification of biochars, and commonly used biochar raw materials * Technologies and key influencing factors in biochar preparation, types and characteristics of carbonation reactors, and migration of alkali metals during biochar combustion * Waste-derived biochar as organic seeding substrate, discussing the growing media of compost, humic acid, and activated carbon * Improvement of soil physical, chemical, and biological properties by waste-derived biochar, covering effects on soil pH, organic matter, and cation exchange quantity Waste-derived Biochar for Sustainable Rural Revitalization serves as an invaluable reference for engineers, scientists, researchers, and graduate students in waste recycling and management, sustainable rural development, environmental engineering, civil engineering, chemical engineering, and related fields.
Yuqing Sun, PhD, is an Associate Professor in School of Agriculture and Biotechnology at Sun Yat-Sen University. She has published over 60 articles in top 10% journals and received over 7,900 citations. Her research covers the customized design and application of engineered biochar in green and sustainable agricultural applications. Prof. Dan Tsang (ICE Fellow, RSC Fellow, HKIE Fellow) is a Professor in Department of Civil and Environmental Engineering and Director of Research Center on Decarbonization Technology at The Hong Kong University of Science and Technology. He has published over 600 articles in top 10% journals and received over 78,000 citations. His research team strives to develop green technologies to ensure sustainable development and long-term decarbonization.
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List of Contributors xvii Preface xxv 1 Tailored Biochar Production from Waste Biomass Resource in Rural Areas 1 Yuqing Sun and Daniel C.W. Tsang 1.1 Introduction 1 1.2 Overview of Rural Solid Wastes 2 1.3 Biochar Production Methods 10 1.4 Biochar Modification Methods 20 1.5 Conclusion 27 2 Waste-derived Biochar as Renewable Bio-fuels 39 Xiefei Zhu, Yuqing Sun, and Daniel C.W. Tsang 2.1 Feedstocks Type of Waste-derived Biochar Fuels 39 2.2 Preparation Technologies of Waste-derived Biochar Fuels 40 2.3 Preparation of Biochar Fuel by Carbonization 44 2.4 Types and Characteristics of Carbonation Reactors 45 2.5 Fuel Properties of Biochar 50 2.6 Combustion of Biochar 53 2.7 Combustion Characteristics of Biochar 55 2.8 Combustion Kinetics of Biochar 60 2.9 Emission Characteristics of Biochar Combustion 62 2.10 Migration of Alkali Metals During Biochar Combustion 64 2.11 Prospects and Challenges of Biochar Energy 68 3 Agricultural Waste-derived Biochar for Energy Recovery from Waste Fermentation 77 Hong-Yu Ren, Qingqing Song, Fanying Kong, and Xueting Song 3.1 Introduction 77 3.2 Biochar Preparation from Agricultural Waste 79 3.3 Energy Recovery from Waste Biomass Fermentation Based on Biochar Treatment 80 3.4 A Case for Biochar in Energy Recovery 83 3.5 Conclusion 83 4 Waste-derived Biochar as Organic Seeding Substrate 87 Yutao Peng, Yuqing Sun, and Daniel C.W. Tsang 4.1 Peat-based Growing Media Substituted by Biochar 87 4.2 Coir-based Growing Media Substituted by Biochar 89 4.3 Growing Media of Compost, Humic Acid, and Activated Carbon 90 5 Waste-derived Biochar as Slow-release Fertilizers 95 Xiaoqian Jiang, Yuqing Sun, and Jing Luo 5.1 Introduction 95 5.2 Research Progress of SRF 96 5.3 The Preparation Technologies of Biochar-based SRFs 99 5.4 Mechanism of Slow Release of Biochar 103 5.5 The Specific Applications of Biochar SRF 104 5.6 Summary and Outlook 106 6 Waste-derived Biochar as Slow-release Pesticides 113 Xiaoqian Jiang, Yuqing Sun, and Jing Luo 6.1 Introduction 113 6.2 Research Progress of Biochar-based Slow-release Pesticides 115 6.3 The Mechanisms of Biochar Loading and Slow Release of Pesticide 117 6.4 Determinants Influencing Biochar Loading Efficiency and Pesticidal Release Capacity 121 6.5 Modification of Biochar for Sustained Release of Pesticide 125 6.6 Summary and Outlook 126 7 Waste-derived Biochar as Targeting Plant Disease Suppressors 133 Mi Wei, Zhongwang Liu, Yuqing Sun, and Jinfang Tan 7.1 Introduction 133 7.2 Methods 134 7.3 Using Biochar for Managing Plant Diseases 134 7.4 Conclusion 142 8 Improvement of Soil Physical, Chemical, and Biological Properties by Waste-derived Biochar 149 Ying Zhao, Zhuqing Liu, Jiang Song, Kui Cheng, and Fan Yang 8.1 Biochar Improves Soil Physical Properties 150 8.2 Biochar Improves Soil Chemical Properties 154 8.3 Biochar Improves Soil Biological Properties 159 9 Impact of Biochar on Pesticides Transportation, Bioavailability, Performance, and Degradation in Soil Environment 169 Xin Liu, Lingfeng Zeng, Yuqing Sun, Yaoyu Zhou, and Daniel C.W. Tsang 9.1 Introduction to Biochar and Pesticides 169 9.2 Biochar Application for Pesticide Control 171 9.3 Biochar's Impact on Pesticide Transportation 175 9.4 Bioavailability of Pesticides in the Presence of Biochar 176 9.5 Performance Enhancement of Pesticides with Biochar 178 9.6 Degradation of Pesticides Influenced by Biochar 179 9.7 Future Prospects and Challenges in Biochar-Pesticide Research 180 10 Waste-derived Biochar as Adsorbent for Agriculture Wastewater Treatment 187 Jianhua Qu and Ying Zhang 10.1 Introduction 187 10.2 Preparation of Biochar-based Agriculture Wastewater Adsorbent 188 10.3 Efficacy of Biochar-adsorption on Agriculture Wastewater Treatment 192 10.4 Effects of Modification Methods on Biochar-enhanced Adsorption Agriculture Wastewater Treatment 196 10.5 Mechanisms of Adsorption and Future Prospects 203 11 Waste-derived Biochar as Catalyst for Agriculture Wastewater Treatment 211 Xiaofei Tan, Hailan Yang, Qiang Chen, and Qianzhen Fang 11.1 Photocatalysis 212 11.2 H2O2-based Catalysis Processes 216 11.3 PS-based Catalysis Processes 218 11.4 PI-based Catalysis Processes 220 11.5 O3-based Catalysis Processes 226 11.6 PAA-based Catalysis Processes 236 12 Waste-derived Biochar for Efficient CO2 Capture 261 Leichang Cao, Jieni Wang, Shuqin Zhang, Haodong Hou, Yuqing Sun, and Daniel C.W. Tsang 12.1 Introduction 261 12.2 Biomass-based Carbon Materials 262 12.3 Activation Methods for Carbon Materials 268 12.4 The Recent Advances of Functionalized Biochar Materials for CO2 Capture 273 12.5 Conclusion and Outlook 282 13 Biomass Waste-derived Biochar as Graphitic Carbon for Agricultural Applications 291 Baojun Yi, Fang Huang, and Jiaqi Deng 13.1 Literature Statistics Methodology 291 13.2 Biomass Waste Feedstocks Suitable for the Preparation of Graphitic Carbon 293 13.3 Graphitization and Carbonization Processes of Waste Biomass and Characteristics of Graphitic Carbon 299 13.4 Optimization Methods for Biomass Waste-derived Graphitic Carbon 305 13.5 Removal of Organic Pollutants from Water and Soil by Waste-derived Graphitic Carbon 315 13.6 Improvement of Soil Properties by Waste-derived Graphitic Carbon 319 13.7 Improvement of Fertilizer Properties by Waste-derived Graphitic Carbon 321 13.8 Immobilization of Heavy Metals by Waste-derived Graphitic Carbon 322 13.9 Conclusions and Prospects 323 14 Waste-derived Biochar for Low-carbon Construction Materials in Rural Areas 351 Fulin Qu, Weijian Xu, Yizhe Wang, Yipu Guo, Su Yilin, and Daniel C.W. Tsang 14.1 Introduction 351 14.2 Properties of Waste-derived Biochar 353 14.3 Treatment and Engineering of Biochar 357 14.4 Applications in Low-carbon Construction 359 14.5 Environmental and Economic Benefits 365 14.6 Conclusion 367 15 Low-carbon Soil Remediation with Biochar and GGBS 373 Weijian Xu, Jingyi Liang, Yuying Zhang, and Daniel C.W. Tsang 15.1 Introduction 373 15.2 Latest Developments and Applications of Biochar in Soil Remediation 374 15.3 Biochar-enhanced Cement for Stabilization/Solidification 382 15.4 Key Parameters in Biochar-enhanced Soil S/S 387 15.5 Supply Availability of Biochar 392 15.6 GGBS Supply Availability 394 15.7 Environmental Benefits 397 15.8 Conclusion 398 16 Technical and Economic Analysis of Biochar Technologies 407 Le Fang, Yifan Xing, and Yingying Han 16.1 Introduction 407 16.2 Techno-economic Analysis of Biochar Technologies in Production Process 408 16.3 Techno-economic Analysis of Biochar Application Scenarios 412 16.4 Element Circulation and Sustainable Development 416 16.5 Current Limitations and Future Perspectives 418 16.6 Summary 418 17 ESG Perspective and Biodiversity Impact of Waste-derived Biochar 425 Maheshika Senanayake, Pavani Dulanja Dissanayake, Jay Hyuk Rhee, Meththika Vithanage, and Yong Sik Ok Graphical Abstract 425 17.1 Introduction 426 17.2 Environmental (E) Perspective 426 17.3 Social (S) Perspective 430 17.4 Governance (G) Perspective 438 17.5 Biodiversity 440 17.6 Challenges and Opportunities 442 17.7 Conclusion 443 Funding 444 Declaration of Competing Interest 444 Data Availability 444 Declaration of Generative AI and AI-assisted Technologies in the Writing Process 444 18 Environmental Stability of Biochar in Natural Systems 455 Shishu Zhu, Lanfang Han, and Ke Sun 18.1 Environmental Reactivity of Biochar 455 18.2 Aggregation and Transport Behaviors of Biochar Colloids 458 18.3 Biochar Carbon Stability 461 18.4 Perspectives 469 19 Risk Assessment of Biochar in Soil and Aquatic Ecosystem 479 Xiaochen Huang, Peng Xie, Huijun Li, and Shih-Hsin Ho 19.1 Negative Impacts of Biochar on Soil Ecosystem 479 19.2 Negative Impacts of Biochar on Aquatic Ecosystem 482 19.3 Combined Effects of Biochar and Pollutants to Organisms 485 19.4 Potential Measures for Risk Avoidance 487 Index 493
List of Contributors xvii Preface xxv 1 Tailored Biochar Production from Waste Biomass Resource in Rural Areas 1 Yuqing Sun and Daniel C.W. Tsang 1.1 Introduction 1 1.2 Overview of Rural Solid Wastes 2 1.3 Biochar Production Methods 10 1.4 Biochar Modification Methods 20 1.5 Conclusion 27 2 Waste-derived Biochar as Renewable Bio-fuels 39 Xiefei Zhu, Yuqing Sun, and Daniel C.W. Tsang 2.1 Feedstocks Type of Waste-derived Biochar Fuels 39 2.2 Preparation Technologies of Waste-derived Biochar Fuels 40 2.3 Preparation of Biochar Fuel by Carbonization 44 2.4 Types and Characteristics of Carbonation Reactors 45 2.5 Fuel Properties of Biochar 50 2.6 Combustion of Biochar 53 2.7 Combustion Characteristics of Biochar 55 2.8 Combustion Kinetics of Biochar 60 2.9 Emission Characteristics of Biochar Combustion 62 2.10 Migration of Alkali Metals During Biochar Combustion 64 2.11 Prospects and Challenges of Biochar Energy 68 3 Agricultural Waste-derived Biochar for Energy Recovery from Waste Fermentation 77 Hong-Yu Ren, Qingqing Song, Fanying Kong, and Xueting Song 3.1 Introduction 77 3.2 Biochar Preparation from Agricultural Waste 79 3.3 Energy Recovery from Waste Biomass Fermentation Based on Biochar Treatment 80 3.4 A Case for Biochar in Energy Recovery 83 3.5 Conclusion 83 4 Waste-derived Biochar as Organic Seeding Substrate 87 Yutao Peng, Yuqing Sun, and Daniel C.W. Tsang 4.1 Peat-based Growing Media Substituted by Biochar 87 4.2 Coir-based Growing Media Substituted by Biochar 89 4.3 Growing Media of Compost, Humic Acid, and Activated Carbon 90 5 Waste-derived Biochar as Slow-release Fertilizers 95 Xiaoqian Jiang, Yuqing Sun, and Jing Luo 5.1 Introduction 95 5.2 Research Progress of SRF 96 5.3 The Preparation Technologies of Biochar-based SRFs 99 5.4 Mechanism of Slow Release of Biochar 103 5.5 The Specific Applications of Biochar SRF 104 5.6 Summary and Outlook 106 6 Waste-derived Biochar as Slow-release Pesticides 113 Xiaoqian Jiang, Yuqing Sun, and Jing Luo 6.1 Introduction 113 6.2 Research Progress of Biochar-based Slow-release Pesticides 115 6.3 The Mechanisms of Biochar Loading and Slow Release of Pesticide 117 6.4 Determinants Influencing Biochar Loading Efficiency and Pesticidal Release Capacity 121 6.5 Modification of Biochar for Sustained Release of Pesticide 125 6.6 Summary and Outlook 126 7 Waste-derived Biochar as Targeting Plant Disease Suppressors 133 Mi Wei, Zhongwang Liu, Yuqing Sun, and Jinfang Tan 7.1 Introduction 133 7.2 Methods 134 7.3 Using Biochar for Managing Plant Diseases 134 7.4 Conclusion 142 8 Improvement of Soil Physical, Chemical, and Biological Properties by Waste-derived Biochar 149 Ying Zhao, Zhuqing Liu, Jiang Song, Kui Cheng, and Fan Yang 8.1 Biochar Improves Soil Physical Properties 150 8.2 Biochar Improves Soil Chemical Properties 154 8.3 Biochar Improves Soil Biological Properties 159 9 Impact of Biochar on Pesticides Transportation, Bioavailability, Performance, and Degradation in Soil Environment 169 Xin Liu, Lingfeng Zeng, Yuqing Sun, Yaoyu Zhou, and Daniel C.W. Tsang 9.1 Introduction to Biochar and Pesticides 169 9.2 Biochar Application for Pesticide Control 171 9.3 Biochar's Impact on Pesticide Transportation 175 9.4 Bioavailability of Pesticides in the Presence of Biochar 176 9.5 Performance Enhancement of Pesticides with Biochar 178 9.6 Degradation of Pesticides Influenced by Biochar 179 9.7 Future Prospects and Challenges in Biochar-Pesticide Research 180 10 Waste-derived Biochar as Adsorbent for Agriculture Wastewater Treatment 187 Jianhua Qu and Ying Zhang 10.1 Introduction 187 10.2 Preparation of Biochar-based Agriculture Wastewater Adsorbent 188 10.3 Efficacy of Biochar-adsorption on Agriculture Wastewater Treatment 192 10.4 Effects of Modification Methods on Biochar-enhanced Adsorption Agriculture Wastewater Treatment 196 10.5 Mechanisms of Adsorption and Future Prospects 203 11 Waste-derived Biochar as Catalyst for Agriculture Wastewater Treatment 211 Xiaofei Tan, Hailan Yang, Qiang Chen, and Qianzhen Fang 11.1 Photocatalysis 212 11.2 H2O2-based Catalysis Processes 216 11.3 PS-based Catalysis Processes 218 11.4 PI-based Catalysis Processes 220 11.5 O3-based Catalysis Processes 226 11.6 PAA-based Catalysis Processes 236 12 Waste-derived Biochar for Efficient CO2 Capture 261 Leichang Cao, Jieni Wang, Shuqin Zhang, Haodong Hou, Yuqing Sun, and Daniel C.W. Tsang 12.1 Introduction 261 12.2 Biomass-based Carbon Materials 262 12.3 Activation Methods for Carbon Materials 268 12.4 The Recent Advances of Functionalized Biochar Materials for CO2 Capture 273 12.5 Conclusion and Outlook 282 13 Biomass Waste-derived Biochar as Graphitic Carbon for Agricultural Applications 291 Baojun Yi, Fang Huang, and Jiaqi Deng 13.1 Literature Statistics Methodology 291 13.2 Biomass Waste Feedstocks Suitable for the Preparation of Graphitic Carbon 293 13.3 Graphitization and Carbonization Processes of Waste Biomass and Characteristics of Graphitic Carbon 299 13.4 Optimization Methods for Biomass Waste-derived Graphitic Carbon 305 13.5 Removal of Organic Pollutants from Water and Soil by Waste-derived Graphitic Carbon 315 13.6 Improvement of Soil Properties by Waste-derived Graphitic Carbon 319 13.7 Improvement of Fertilizer Properties by Waste-derived Graphitic Carbon 321 13.8 Immobilization of Heavy Metals by Waste-derived Graphitic Carbon 322 13.9 Conclusions and Prospects 323 14 Waste-derived Biochar for Low-carbon Construction Materials in Rural Areas 351 Fulin Qu, Weijian Xu, Yizhe Wang, Yipu Guo, Su Yilin, and Daniel C.W. Tsang 14.1 Introduction 351 14.2 Properties of Waste-derived Biochar 353 14.3 Treatment and Engineering of Biochar 357 14.4 Applications in Low-carbon Construction 359 14.5 Environmental and Economic Benefits 365 14.6 Conclusion 367 15 Low-carbon Soil Remediation with Biochar and GGBS 373 Weijian Xu, Jingyi Liang, Yuying Zhang, and Daniel C.W. Tsang 15.1 Introduction 373 15.2 Latest Developments and Applications of Biochar in Soil Remediation 374 15.3 Biochar-enhanced Cement for Stabilization/Solidification 382 15.4 Key Parameters in Biochar-enhanced Soil S/S 387 15.5 Supply Availability of Biochar 392 15.6 GGBS Supply Availability 394 15.7 Environmental Benefits 397 15.8 Conclusion 398 16 Technical and Economic Analysis of Biochar Technologies 407 Le Fang, Yifan Xing, and Yingying Han 16.1 Introduction 407 16.2 Techno-economic Analysis of Biochar Technologies in Production Process 408 16.3 Techno-economic Analysis of Biochar Application Scenarios 412 16.4 Element Circulation and Sustainable Development 416 16.5 Current Limitations and Future Perspectives 418 16.6 Summary 418 17 ESG Perspective and Biodiversity Impact of Waste-derived Biochar 425 Maheshika Senanayake, Pavani Dulanja Dissanayake, Jay Hyuk Rhee, Meththika Vithanage, and Yong Sik Ok Graphical Abstract 425 17.1 Introduction 426 17.2 Environmental (E) Perspective 426 17.3 Social (S) Perspective 430 17.4 Governance (G) Perspective 438 17.5 Biodiversity 440 17.6 Challenges and Opportunities 442 17.7 Conclusion 443 Funding 444 Declaration of Competing Interest 444 Data Availability 444 Declaration of Generative AI and AI-assisted Technologies in the Writing Process 444 18 Environmental Stability of Biochar in Natural Systems 455 Shishu Zhu, Lanfang Han, and Ke Sun 18.1 Environmental Reactivity of Biochar 455 18.2 Aggregation and Transport Behaviors of Biochar Colloids 458 18.3 Biochar Carbon Stability 461 18.4 Perspectives 469 19 Risk Assessment of Biochar in Soil and Aquatic Ecosystem 479 Xiaochen Huang, Peng Xie, Huijun Li, and Shih-Hsin Ho 19.1 Negative Impacts of Biochar on Soil Ecosystem 479 19.2 Negative Impacts of Biochar on Aquatic Ecosystem 482 19.3 Combined Effects of Biochar and Pollutants to Organisms 485 19.4 Potential Measures for Risk Avoidance 487 Index 493
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