Note: Intro -- Foreword -- Preface -- Contents -- In-Situ Remediation Approaches for the Management of Contaminated Sites: A Comprehensive Overview -- 1 Introduction -- 2 Selection and Suitability of Remedial Measures -- 3 In-Situ Remediation Technologies for Soil and Groundwater -- 3.1 Heating -- 3.1.1 Injection: Steam/Hot Air -- 3.1.2 Electrical Resistance Heating -- 3.1.3 Electromagnetic Heating: Radio Frequency/Microwave -- 3.1.4 Thermal Conductive Heating/Thermal Desorption -- 3.1.5 Vitrification -- 3.2 Soil Flushing -- 3.3 Fracturing: Pneumatic/Blast-Enhanced/Lasagna™/Hydro -- 3.4 Physical Barriers: Treatment Walls/Permeable Reactive Barriers -- 3.5 Soil Vapor Extraction -- 3.6 Electrokinetic Remediation -- 3.7 Multi 3-Phase/Dual-Phase/Vacuum-Enhanced Extraction/Bioslurping -- 3.8 Air Sparging -- 3.9 Bioventing -- 3.10 Natural Attenuation -- 3.11 Phytoremediation -- 3.12 Bioaugmentation -- 3.13 Biostimulation -- 3.14 Biosorption -- 4 Emerging Technologies -- 4.1 Microbial Fuel Cells -- 4.2 Nanoremediation -- 4.3 Transgenic Plants and Microbes -- 4.4 Microbial Consortia in Photo-Hetero Microbial System -- 5 Challenges and Prospects -- 6 Summary -- References -- Ex-Situ Remediation Technologies for Environmental Pollutants: A Critical Perspective -- 1 Introduction -- 2 Ex-Situ vs. In-Situ Remediation -- 3 Existing Ex-Situ Remedial Options for Contaminated Soil and Groundwater: Technology Profile and Recent Advances -- 3.1 Dig-and-Dump (Landfills and Engineered Landfills) -- 3.2 Pump-and-Treat -- 3.3 Incineration -- 3.4 Oxidation -- 3.5 Adsorption -- 3.6 Ion-Exchange -- 3.7 Pyrolysis -- 3.8 Soil Washing -- 3.9 Dehalogenation -- 3.10 Solid-Phase Bioremediation -- 3.10.1 Biopiles -- 3.10.2 Landfarming -- 3.10.3 Composting -- 3.11 Slurry-Phase Bioremediation: Bioreactors -- 3.12 Solidification/Stabilization -- 3.13 Constructed Wetlands. , 4 Ex-Situ Technologies for Air Pollution Control -- 5 Emerging Ex-Situ Remediation Technologies -- 5.1 Ultrasonic Technology -- 5.2 Microbial Fuel Cells, Nanoremediation and Others -- 6 Future Research Needs -- 7 Summary -- References -- Lead Exposure and Oxidative Stress: A Systematic Review -- 1 Introduction -- 2 Sources and Types of Epidemiological Evidence -- 3 Lead-Induced Oxidative Stress in the General Population -- 4 Lead-Induced Oxidative Stress in Occupationally Exposed Populations -- 5 Types and Utility of Biomarkers -- 6 Conclusions -- 7 Summary -- Appendix 1: Search Strategy -- References -- Nanostructured Metal Oxides for Stoichiometric Degradation of Chemical Warfare Agents -- 1 Introduction -- 2 Nanostructured Oxides -- 2.1 Oxides of Alkaline Earth Metals -- 2.2 Aluminum Oxide -- 2.3 Zinc Oxide -- 2.4 Titanium Oxide -- 2.4.1 Zr4+ and Hf4+-Doped Titania -- 2.4.2 Ge4+ and In3+ Doped Titania -- 2.4.3 Titania, Iron and Manganese Mixed Oxides -- 2.5 Zero-Valent Iron and Iron Oxides -- 2.6 Zirconium Hydroxide -- 2.7 Manganese Oxide (MnO2) -- 2.8 Vanadium Oxide -- 2.9 Ce3+ and Ce4+ Oxides -- 3 Conclusions -- References -- Ecological Recovery Potential of Freshwater Organisms: Consequences for Environmental Risk Assessment of Chemicals -- 1 Introduction -- 2 Stressor Types, Case Studies and Recovery Estimates Covered by the Review -- 3 Variability in Recovery Times Among Taxonomic Groups -- 3.1 Algae -- 3.2 Zooplankton -- 3.3 Fish -- 3.4 Macro-invertebrates -- 3.4.1 Diptera -- 3.4.2 Ephemeroptera -- 3.4.3 Oligochaeta -- 3.4.4 Macro-crustacea -- 3.4.5 Plecoptera -- 3.4.6 Trichoptera -- 3.4.7 Heteroptera -- 3.4.8 Odonata -- 3.4.9 Coleoptera -- 3.4.10 Mollusca -- 3.5 Macrophytes -- 4 Contributions of Ecosystem Type, Landscape Characteristics and Community Processes -- 5 Variability in Recovery Times among Stressor Types. , 6 Comparison of Semi-field and Field Recovery Times -- 7 The Role of Effect Size in Recovery Time Estimation -- 8 Limitations for the Derivation of Recovery Times -- 9 Risk Assessment, Ecological Recovery and Legislation -- 10 Summary -- References -- Index.