Improved understanding of hyperaccumulation yields commercial phytoextraction and phytomining technologies.
about
Cellular sequestration of cadmium in the hyperaccumulator plant species Sedum alfredii.Natural variation among Arabidopsis accessions reveals malic acid as a key mediator of Nickel (Ni) tolerance.The metal hyperaccumulators from New Caledonia can broaden our understanding of nickel accumulation in plantsLocalized metal solubilization in the rhizosphere of Salix smithiana upon sulfur applicationMining in New Caledonia: environmental stakes and restoration opportunities.Phytoextraction from mine spoils: insights from New Caledonia.Transfer of heavy metals through terrestrial food webs: a review.Copper and cobalt accumulation in plants: a critical assessment of the current state of knowledge.PHYTOREMEDIATION OF INORGANICS: REALISM AND SYNERGIES.Phytoextraction of Cd-Contaminated Soils: Current Status and Future Challenges.Transient Influx of nickel in root mitochondria modulates organic acid and reactive oxygen species production in nickel hyperaccumulator Alyssum murale.Nickel biopathways in tropical nickel hyperaccumulating trees from Sabah (Malaysia)Microbeam methodologies as powerful tools in manganese hyperaccumulation research: present status and future directions.Compartmentation and complexation of metals in hyperaccumulator plantsLeaf-age and soil-plant relationships: key factors for reporting trace-elements hyperaccumulation by plants and design applications.Agronomic Practices for Improving Gentle Remediation of Trace Element-Contaminated Soils.A metaproteomic approach dissecting major bacterial functions in the rhizosphere of plants living in serpentine soil.Biochar and Glomus caledonium influence Cd accumulation of upland kangkong (Ipomoea aquatica Forsk.) intercropped with Alfred stonecrop (Sedum alfredii Hance).Combined endophytic inoculants enhance nickel phytoextraction from serpentine soil in the hyperaccumulator Noccaea caerulescens.Local Community Perceptions of Mine Site Restoration Using Phytoremediation in Abitibi-Temiscamingue (Quebec).Phytoremediation of cadmium-contaminated soils by young Douglas fir trees: effects of cadmium exposure on cell wall composition.Assessment of Ni accumulation capability by fungi for a possible approach to remove metals from soils and waters.Remediation of soils contaminated with heavy metals with an emphasis on immobilization technology.Multi-element concentrations in plant parts and fluids of Malaysian nickel hyperaccumulator plants and some economic and ecological considerations.Surface display of metal fixation motifs of bacterial P1-type ATPases specifically promotes biosorption of Pb(2+) by Saccharomyces cerevisiae.Gomphrena claussenii, the first South-American metallophyte species with indicator-like Zn and Cd accumulation and extreme metal tolerance.Accumulation and tolerance characteristics of zinc in Agropyron cristatum plants exposed to zinc-contaminated soil.Modeling the plant-soil interaction in presence of heavy metal pollution and acidity variations.The metal transporter PgIREG1 from the hyperaccumulator Psychotria gabriellae is a candidate gene for nickel tolerance and accumulation.Development of a model to select plants with optimum metal phytoextraction potential.Uptake, sequestration and tolerance of cadmium at cellular levels in the hyperaccumulator plant species Sedum alfredii.From phytoremediation of soil contaminants to phytomanagement of ecosystem services in metal contaminated sites.Extreme nickel hyperaccumulation in the vascular tracts of the tree Phyllanthus balgooyi from Borneo.Increased lead and cadmium tolerance of Typha angustifolia from Huaihe River is associated with enhanced phytochelatin synthesis and improved antioxidative capacity.Improving the Agronomy of Alyssum murale for Extensive Phytomining: A Five-Year Field Study.Selection and combustion of Ni-hyperaccumulators for the phytomining process.Bacteria associated with yellow lupine grown on a metal-contaminated soil: in vitro screening and in vivo evaluation for their potential to enhance Cd phytoextraction.A global database for plants that hyperaccumulate metal and metalloid trace elements.Growth and Cadmium Phytoextraction by Swiss Chard, Maize, Rice, Noccaea caerulescens, and Alyssum murale in Ph Adjusted Biosolids Amended Soils.Variations in chromium tolerance and accumulation among canola (Brassica napus L.) cultivars.
P2860
Q34057110-CEEFBD5E-B5B8-4B2D-A71F-1551004DAF8EQ34192549-328B72C4-B3E2-42D3-B0FD-D0E36DF2E65BQ34360695-CA594E58-2447-452C-9D35-1A1C77B1B613Q34467565-C44F6192-F87C-4B92-BB1C-7EEF3BD5DC1DQ35213696-3A43E031-492E-4DE4-9F53-B7BBDB582903Q35453102-5349BA1D-4A8A-4CC7-BC72-B2BF346604BDQ35584649-F58D3407-4285-4C72-AE52-96CB80BB3CB1Q36131982-6897128E-780E-4D63-82F2-3D2941FDB148Q36263568-92F99FAE-CC3B-4D40-950B-A1ECCD8F5EA4Q36536189-05212E3E-0CB8-4466-99FE-2663246D7342Q36666289-3EA162CC-056D-4F43-99D4-5C93437D2C1AQ37644363-DF6D7480-9FEC-40DE-B06E-194C97AD1E0CQ38130932-88DDB13A-ABC0-4B4A-AF74-010705E42E42Q38143023-23F06371-D46F-4885-8506-36A01BD54DCEQ38241375-EAD7D408-FA58-43AA-B6D0-86357704BAABQ38315201-3A2130EA-5DC7-4811-BD87-EC149F16346CQ38438176-7402812A-FB74-4DD7-A1CA-16184EA94E47Q38727070-2A7C70F0-908C-44A5-922F-87D4DC8744EBQ38969087-C6BF352F-A885-44B6-9D79-407F0DAB0562Q38981500-DBD86EDD-4538-4C33-9890-E8E07848FEDFQ39175266-33DE63B0-89AA-487F-B544-F2BB9C392C87Q39191948-C3A449C2-1D0D-4241-B390-E4954A1CB4FAQ39266037-B2E28437-C44E-4A96-B321-0B0C7A8DBC34Q39548881-50278C2D-38BA-4D01-832E-D35C270996C1Q39891288-3E119C39-5E39-4F02-AAB2-1F12F0F011EAQ42143089-9A2A01B3-4A3D-4F41-B79E-1A890FD0BF5BQ43828779-3B101FE6-E464-4C38-97BE-4BCF41E50D93Q44550510-545B7835-2044-4BE1-8E43-DB079275F2D0Q45344847-E80B145F-98D2-48D0-BBD7-B6774062C95FQ45955758-1CD6ACD7-9198-4D5F-A061-A14437298339Q46284211-DE8F55D4-7EC1-40D0-B6D9-F7A20BFF817DQ46313321-D581C4C7-21E8-4B69-8025-7CDBAE9FF476Q46527597-14332C8B-4A49-4B3C-875C-29E4C6E23A41Q46582608-CAA57E66-924C-4BDA-BE9C-A15E9C120A7CQ46836583-57D87D2E-B833-4D41-B092-9476CFCB0E09Q46878941-7FBF2750-FBF4-46B2-ABE3-7A7E68B52068Q46949471-9D7D4D7E-1105-43A1-9D71-81980615BC2EQ48302500-15D4B816-AC80-47B4-ABB9-208547947A79Q50450279-98B55645-1233-47E7-BDCA-BC36F995335DQ50459105-8410F601-0A4A-4268-8E66-D6241BE21223
P2860
Improved understanding of hyperaccumulation yields commercial phytoextraction and phytomining technologies.
description
2007 nî lūn-bûn
@nan
2007年の論文
@ja
2007年論文
@yue
2007年論文
@zh-hant
2007年論文
@zh-hk
2007年論文
@zh-mo
2007年論文
@zh-tw
2007年论文
@wuu
2007年论文
@zh
2007年论文
@zh-cn
name
Improved understanding of hype ...... and phytomining technologies.
@en
type
label
Improved understanding of hype ...... and phytomining technologies.
@en
prefLabel
Improved understanding of hype ...... and phytomining technologies.
@en
P2093
P356
P1476
Improved understanding of hype ...... and phytomining technologies.
@en
P2093
C Leigh Broadhurst
Carinne A Peters
Donald L Sparks
J Scott Angle
Rufus L Chaney
Ryan V Tappero
P304
P356
10.2134/JEQ2006.0514
P577
2007-08-31T00:00:00Z