Linked e-resources
Details
Table of Contents
Intro; Preface; Contents; Contributors; 1 Arsenic Distribution and Pollution Characteristics; 1.1 Mineralogy and Distribution of Arsenic; 1.1.1 Arsenic-Containing Minerals; 1.1.2 Distribution of Arsenic Minerals; 1.1.3 Transformation Behavior of Arsenic Mineralogical Phase; 1.2 Pollution Sources of Arsenic; 1.2.1 Natural Pollution Sources; 1.2.2 Anthropogenic Pollution Sources; 1.3 Arsenic Pollution Characteristics and Status in Environment; 1.3.1 Arsenic Pollution in Groundwater; 1.3.2 Arsenic Pollution in Atmosphere; 1.3.3 Arsenic Pollution in Solid Phase; References
2 Pollution Source Distribution of Arsenic in the Typical Smelter2.1 Behavior and Distribution of Arsenic in a Typical Lead Smelter; 2.1.1 Arsenic Behavior in SKS Lead Smelting Process; 2.1.2 Characterization of Dust and Slag Samples; 2.2 Environment Risk Assessment; References; 3 Arsenic Behaviors and Pollution Control Technologies in Aqueous Solution; 3.1 Introduction; 3.2 Redox Behavior and Chemical Species of Arsenic in Acidic Aqueous System; 3.2.1 Redox Behavior of Arsenic; 3.2.2 Chemical Species of Arsenic; 3.2.3 Eh-pH Diagram in Fe-As-H2O System; 3.2.4 Fe(III)-As(V) Complexes
3.2.5 Species Transformation of Fe(III)-As(V) Complexes3.3 Photochemical Oxidation of As(III) and the Molecular Reaction Mechanism; 3.3.1 The SO4·−-Based As(III) Oxidation; 3.3.2 Kinetics of Oxidation Reaction; 3.3.3 Molecular Reaction Mechanism; 3.4 Formation Mechanism and Characteristics of Tooeleite from High-Arsenic Acid Wastewater; 3.4.1 Direct Removal of As(III) by the Formation of Tooeleite; 3.4.2 Characterization of Tooeleite; 3.4.3 Safety Evaluation; 3.4.4 Tooeleite Formation Mechanism; 3.5 Cascade Sulfide Precipitation and Separation of Copper and Arsenic from Acidic Wastewater
3.5.1 Thermodynamics for Separation of Copper and Arsenic3.5.2 Cascade Sulfide Precipitation and Separation Technique; 3.5.3 Removal Efficiencies of Copper and Arsenic; 3.5.4 Replacement of Arsenic by Copper; 3.6 Arsenic Removal by Fe3O4-Based Nanomaterials via Adsorption; 3.6.1 Controllable Synthesis of Hierarchical Porous Fe3O4 Particles for Arsenic Removal; 3.6.2 Arsenic Adsorption by Cu Doped Fe3O4 Magnetic Adsorbent; 3.6.3 Arsenic Adsorption by Fe3O4@Cu(OH)2 Composites; 3.6.4 Arsenic Removal by Hollow Cu-Loaded Poly(m-Phenylenediamine) Particles; References
4 Arsenic Pollution Control Technologies for Arsenic-Bearing Solid Wastes4.1 Arsenic Stabilization Technologies; 4.1.1 Lime-Based Stabilization of High Alkaline Arsenic-Bearing Sludges; 4.1.2 Stabilization of Arsenic Sludge with Mechanochemically Modified Zero Valent Iron; 4.2 Arsenic Solidification Technologies; 4.2.1 Solidification/Stabilization of Arsenic and Heavy Metals with Minimal Cement Clinker; 4.2.2 Co-treatment of Gypsum Sludge and Pb/Zn Smelting Slag; 4.2.3 Utilization of Red Mud and Arsenic Sludge for the Synthesis of a Red Mud-Based Cementitious Material; 4.3 Arsenic Vitrification Technologies
2 Pollution Source Distribution of Arsenic in the Typical Smelter2.1 Behavior and Distribution of Arsenic in a Typical Lead Smelter; 2.1.1 Arsenic Behavior in SKS Lead Smelting Process; 2.1.2 Characterization of Dust and Slag Samples; 2.2 Environment Risk Assessment; References; 3 Arsenic Behaviors and Pollution Control Technologies in Aqueous Solution; 3.1 Introduction; 3.2 Redox Behavior and Chemical Species of Arsenic in Acidic Aqueous System; 3.2.1 Redox Behavior of Arsenic; 3.2.2 Chemical Species of Arsenic; 3.2.3 Eh-pH Diagram in Fe-As-H2O System; 3.2.4 Fe(III)-As(V) Complexes
3.2.5 Species Transformation of Fe(III)-As(V) Complexes3.3 Photochemical Oxidation of As(III) and the Molecular Reaction Mechanism; 3.3.1 The SO4·−-Based As(III) Oxidation; 3.3.2 Kinetics of Oxidation Reaction; 3.3.3 Molecular Reaction Mechanism; 3.4 Formation Mechanism and Characteristics of Tooeleite from High-Arsenic Acid Wastewater; 3.4.1 Direct Removal of As(III) by the Formation of Tooeleite; 3.4.2 Characterization of Tooeleite; 3.4.3 Safety Evaluation; 3.4.4 Tooeleite Formation Mechanism; 3.5 Cascade Sulfide Precipitation and Separation of Copper and Arsenic from Acidic Wastewater
3.5.1 Thermodynamics for Separation of Copper and Arsenic3.5.2 Cascade Sulfide Precipitation and Separation Technique; 3.5.3 Removal Efficiencies of Copper and Arsenic; 3.5.4 Replacement of Arsenic by Copper; 3.6 Arsenic Removal by Fe3O4-Based Nanomaterials via Adsorption; 3.6.1 Controllable Synthesis of Hierarchical Porous Fe3O4 Particles for Arsenic Removal; 3.6.2 Arsenic Adsorption by Cu Doped Fe3O4 Magnetic Adsorbent; 3.6.3 Arsenic Adsorption by Fe3O4@Cu(OH)2 Composites; 3.6.4 Arsenic Removal by Hollow Cu-Loaded Poly(m-Phenylenediamine) Particles; References
4 Arsenic Pollution Control Technologies for Arsenic-Bearing Solid Wastes4.1 Arsenic Stabilization Technologies; 4.1.1 Lime-Based Stabilization of High Alkaline Arsenic-Bearing Sludges; 4.1.2 Stabilization of Arsenic Sludge with Mechanochemically Modified Zero Valent Iron; 4.2 Arsenic Solidification Technologies; 4.2.1 Solidification/Stabilization of Arsenic and Heavy Metals with Minimal Cement Clinker; 4.2.2 Co-treatment of Gypsum Sludge and Pb/Zn Smelting Slag; 4.2.3 Utilization of Red Mud and Arsenic Sludge for the Synthesis of a Red Mud-Based Cementitious Material; 4.3 Arsenic Vitrification Technologies