Phytoremediation of Contaminated Soil and Water

Norman Terry , Gary Bañuelos

Field Demonstrations of Phytoremediation of Lead Contaminated Soils
Phytoremediation by Constructed Wetlands
Factors Influencing Field Phytoremediations of Selenium-Laden Soils
Phytoremediation of Selenium-Polluted Soils and Waters by Phytovolitization
Metal Hyperaccumulator Plants: a Review of the Ecology and Physiology of a Biological Resource For Phytoremediation Of Metal-Polluted Soils -
Potential for Phytoextraction of Zinc and Cadmium from Soils Using Hyperaccumulator Plants
Improving Metal Hyperaccumulator Wild Plants to Develop Commercial Phytoextraction Systems: Approach and Progress
Physiology of Zn Hyperaccumulation in Thlaspi caerulescens
Metal-Specific Patterns of Tolerance, Uptake, and Transport of Heavy Metals in Hyperaccumulating and Non-Hyperaccumulating Metallophytes
The Role of Root Exudates in Nickel Hyperaccumulation and Tolerance in Accumulator and Nonaccumulator Species of Thlaspi
Engineered Phytoremediation of Mercury Pollution in Soil and Water Using Bacterial Genes
Metal Tolerance in Plants: The Role of Phytochelatins and Metallothioneins
The Genetics of Metal Tolerance and Accumulation in Higher Plants
Ecological Genetics and the Evolution of Trace Element Hyperaccumulation in Plants
The Role of Bacteria in the Phytoremediation of Heavy Metals
Microphyte-Mediated Biogeochemistry and Its Role in In Situ Selenium Bioremediation
In Situ Gentle Remediation Measures For Heavy Metal Polluted Soils
In Situ Metal Immobilization and Phytostabilization of Contaminated Soils
Phytoextraction or In-Place Inactivation (Phytostabilization): Technical, Economic, and Regulatory Considerations of the Soil-Lead Issue

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