Heipieper, H. ed.
Bioremediation of Soils Contaminated with Aromatic Compounds
Springer-Verlag 2007.1
155 pp. (H)
ISBN 1-4020-5691-5
21,000円
Proceedings of the NATO Advanced Research Workshop on Bioremediation of Soils Contaminated with Aromatic Compounds, Tartu, Estonia, 1-3 July 2004
Contents
1.Bioremediation of soils contaminated with aromatic compounds:effects of rhizosphere, bioavailability, gene regulation and stress adaptation/ 2. Influence of the rhizosphere on the biodegradation of organic xenobiotics - a case study with acid 2,4-dichlorophenoxyacetic acid/ 3.Regulation of the atrazine degradative pathway in Pseudomonas/ 4.The role of plants and bacteria in phytoremediation - kinetic aspects/ 5.Regularities in the oxidizing metabolism of bacteria/ 6.Formation of microbial conmunities in oil shale chemical industry solid wastes during and bioaugmentation/ 7.Studies on biodegradation of aromatic pollutants by Trichosroron cutaneum yeast strain/ 8.The potential of keratinolytic and keratinophilic fungi for degradation of petroleum hydrocarbons in soil/ 9. Study of contaminatjon and migration polychlorinated biphenyls in the environment. Bioremediation of contaminated soils and assessment of their impact on the serpukhov population health/ 10.Shedding light on the bioavailability, of organic pollutants/ 11.Reduction of chromium (VI) by bacteria collection strains of different physiologic groups/ *
Twardowska, I. et al.
Viable Methods of Soil and Water Pollution Monitoring, Protection
and Remediation
Springer-Verlag 2006.
629 pp. (H)
ISBN 1-4020-4726-6
36,200円
Proceedings of the NATO Advanced Research Workshop on Viable Methods of Soil and Water Pollution Monitoring, Protection and Remediation, Krakow, Poland, 27 June - 1 July 2005
Contents
Preface. Acknowledgements. Contributors.- 1. Introduction: Spread and Distribution of Hazardous Chemicals in Soils and Water ― A Global Problem 1.1. Diagnosis and prognosis of the distribution of contaminants in the geosphere/ 1.2. Persistent organic pollutants in Egypt - an overview/ 2. Fate and Behavior of Anthropogenic Pollutants in Soils and Water. 2.1. Fundamental Issues in Sorption Related to Physical and Biological Remediation of Soils/ 2.2. The role of humic substances in the fate of anthropogenic organic pollutants in soil with emphasis on endocrine disruptor compounds/ 2.3. Incorporating bioavailability into criteria for metals/ 2.4. The metal uptake and accumulation in fish living in polluted waters/ 3. Advances in Chemical and Biological Techniques for Environmental Monitoring and Predicting. 3.1. Sensoristic approach to biological damage and risk assessment/ 3.2. Advanced environmental biochemical sensor for water monitoring. Automated Water Analyser Computer Supported System (AWACSS)/ 3.3. Genetically engineered microorganisms for pollution monitoring/ 3.4. Some advances in environmental analytics and monitoring/ 3.5. Fiber optic system for water spectroscopy/ 3.6. Predicting metal uptake by plants using DGT technique/ 3.7. On conceptual and numerical modeling of flow and transport in groundwater with the aid of tracers: a case study/ 4. Novel Physico-Chemical Techniques of Soil and Water Protection and Remediation. 4.1. Current and future in situ treatment techniques for the remediation of hazardous substances in soil, sediments, and groundwater/ 4.2. Long-term performance of permeable reactive barriers: lessons learned on design, contaminant treatment, longevity, performance monitoring and cost ― an overview/ 4.3. Using abundant waste and natural materials for soil and groundwater protection against contamination with heavy metals. Prospects and areas of application/ 4.4. Mediating effects of humic substances in the contaminated environments. Concepts, results, and prospects/ 4.5. Metal binding by humic substances and dissolved organic matter derived from compost/ 4.6. The effect of organic matter from brown coal on bioavailability of heavy metals in contaminated soils/ 4.7. Use of activated carbon for soil bioremediation/ 4.8 Adsorption of anions onto sol-gel generated double hydrous oxides/ 4.9. Xenobiotic pharmaceuticals in water and methods to prevent their appearance in drinking water. Photolytic and Photocatalytic Degradation of Pharmaceuticals/ 4.10. UV/VIS light-enhanced photocatalysis for water treatment and protection/ 4.11..New horizons in purification of liquids. Novel colloidal and interfacial strategies to remove hazardous molecules, viruses and other microorganisms from water/ 4.12. Fly ash-organic byproduct mixture as soil amendment / 5. Biosystems for Non-Destructive Remediation and Immobilization of Pollutants in Soils, Sediments and Detoxification of Industrial Wastes. 5.1. Phytoremediation and phytotechnologies: a review for the present and the future/ 5.2. Constructed wetlands and their performance for treatment of water contaminated with arsenic and heavy metals/ 5.3. Disposal of sewage effluent and biosolids in eucalyptus plantations: a lysimeter simulation study/ 5.4. Phytoremediation of explosives in toxic wastes/ 5.5. Floating aquatic macrophytes as a decontamination tool for antimicrobial drugs/ 5.6. Plant tolerance to heavy metals, a risk for food toxicity or a means for food fortification with essential metals: the Allium Schoenoprasum model/ 6. Assembled Plant and Microbial Technologies for Bioremediation of Pollutants. 6.1. Ecoremediation. Cooperation between plants and soil microorganisms, molecular aspects and limits/ 6.2. Anaerobic dehalogenation of halogenated organic compounds: novel strategies for bioremediation of contaminated sediments/ 6.3. Molecular tools for microbial remediation - contaminants uptake, metabolism and biosensing/ 6.4. Role of mycorrhizal fungi in phytoremediation and toxicity monitoring of heavy metal rich industrial wastes in Southern Poland/ 6.5. Biodegradation of petroleum hydrocarbons by keratinolytic fungi/ 7. Management strategies for large-area contaminated sites. 7.1. Integrated management strategy for complex groundwater contamination at a megasite scale/ 7.2. Management options for regionally contaminated aquifers: a case study at Bitterfeld, Germany/ Subject Index/ *
Hamon, R. et al. ed.
Natural Attenuation of Trace Element Availability in Soils
CRC Press 2006.10
256 pp.(H)
ISBN 1-4200-4282-3
19,400円
Contents
1.Natural Attenuation of Trace Element Availability in Soils Assessed by Chemical Extraction. 2.Techniques for Measuring Attenuation: 3.Isotopic Dilution Methods. 4.Biological Assessment of Natural Attenuation of Metals in Soil. 5.Long-Term Fate of Metal Contaminants in Soils and Sediments: 6.Role of Intraparticle Diffusion in Hydrous Metal Oxides. 7.Structural Dynamics of Metal Partitioning to Mineral Surfaces. 8.Effects of Humic Substances on Attenuation of Metal Bioavailability and Mobility in Soil. 9.Attenuation of Metal Toxicity in Soils by Biological Processes. 10.Redox Processes and Attenuation of Metal Availability in Soils. 11.Fixation of Cadmium and Zinc in Soils: Implications for Risk Assessment. 12.Natural Attenuation: Implications for Trace Metal/Metalloid Nutrition. 13.Use of Soil Amendments to Attenuate Trace Element Exposure: Sustainability, Side Effects, and Failures/
* Offering a concise, well-rounded perspective from pioneers in the field, Natural Attenuation of Trace Element Availability in Soils demonstrates how attenuation processes can significantly impact strategies for soil remediation and serve as a basis for environmental regulations. *
Singh, S. N. & Tripathi, R. D. ed.
Environmental Bioremediation Technologies
Springer-Verlag 2007.1
518 pp. (H)
ISBN 3-540-34790-9
25,400円
Contents
1.Bioremediation of Organic and Metal Co-contaminated Environments.- 2.New Bioremediation Technologies to Remove Heavy Metals and Radionuclides using Fe (III),- 3.Sulfate- and Sulfur- Reducing Bacteria.- 4.Bioremediation of Soils Polluted with Hexavalent Chromium using Bacteria.- 5.Accumulation and Detoxification of Metals by Plants and Microbes.- 6.Role of Phytochelatins in Phytoremediation of Heavy Metals.- 7.Metal Resistance in Plants.- 8.Bioremediation of Metals.- 9.Phytoremediation of Metals and Radionuclides.- 10.Nanotechnology for Bioremediation of Heavy Metals.- 11.Aquatic Plants for Phytotechnology.- 12.Phytoremediation of Air Pollutants.- 13.The Role of Macrophytes in Nutrient Removal.- 14.Nitrate Pollution and its Remediation.- 15.Bioremediation of Petroleum Sludge.- 16.Diversity, Biodegradation and Bioremediation of Polycyclic Aromatic Hydrocarbons.- 17.Environmental Applications of Fungal and Plant Systems.- 18.Fungal-Based Remediation.- 19.Biofilms in Porous Media/
* The rapid expansion and increasing sophistication of various industries in the past century has remarkably increased the amount and complexity of toxic waste effluents, which may be bioremediated by suitable plants & microbes, either natural occurring or tailor-made for the specific purpose. This technology is termed as bioremediation. *
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