Interaction of Cd/Zn hyperaccumulating plant (Sedum alfredii) and rhizosphere bacteria on metal uptake and removal of phenanthrene

Journal of Hazardous Materials

Volumn 209-210, Issue , 2012, Pages 421-433

  Li, W C ^a   Wong, M H ^a,b  

^a HONG KONG BAPTIST UNIVERSITY   (Hong Kong)

^b ZHEJIANG A F UNIVERSITY   (China)

Author keywords

Acid phosphatase; Burkholderia cepacia; Dehydrogenase; PAHs; Phytoextraction efficiency; Sedum alfredii; Tolerance index; Translocation factor

Indexed keywords

ACID PHOSPHATASE; BURKHOLDERIA CEPACIA; DEHYDROGENASE; PAHS; PHYTOEXTRACTION; SEDUM ALFREDII; TOLERANCE INDICES; TRANSLOCATION FACTOR;

ANTHRACENE; BACTERIA; BIOCHEMISTRY; BIOREMEDIATION; DETOXIFICATION; LEAD; PHOSPHATASES; SOIL POLLUTION; SOIL POLLUTION CONTROL; SOILS; ZINC;

METALS;

ARSENIC; CADMIUM; COPPER; LEAD; PHENANTHRENE; ZINC;

BACTERIUM; BIOLOGICAL UPTAKE; CADMIUM; COPPER; DEGRADATION; DETOXIFICATION; DICOTYLEDON; ENZYME ACTIVITY; GROWTH RATE; HYPERACCUMULATION; PAH; PHENANTHRENE; PHOSPHATASE; PHYTOREMEDIATION; POLLUTANT REMOVAL; POLLUTION TOLERANCE; RHIZOSPHERE; SOIL POLLUTION; TRANSLOCATION; ZINC;

ARTICLE; BURKHOLDERIA CEPACIA; DEGRADATION KINETICS; DETOXIFICATION; HEAVY METAL REMOVAL; NONHUMAN; PHYTOREMEDIATION; PLANT; PLANT GROWTH; PLANT MICROORGANISM INTERACTION; PLANT ROOT; RHIZOSPHERE BACTERIUM; RHIZOSPHERE INOCULATION; SEDUM ALFREDII; SOIL POLLUTION CONTROL;

BACTERIA; BIOMASS; CADMIUM; HYDROGEN-ION CONCENTRATION; PHENANTHRENES; SEDUM; SOIL MICROBIOLOGY; SOIL POLLUTANTS; ZINC;

BURKHOLDERIA CEPACIA; SEDUM ALFREDII;

EID: 84862820898     PISSN: 03043894     EISSN: 18733336     Source Type: Journal    
DOI: 10.1016/j.jhazmat.2012.01.055     Document Type: Article

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