Phytoremediation of Mercury- and Methyl Mercury-Contaminated Sediments by Water Hyacinth (Eichhornia crassipes)

Phytoremediation has the potential for implementation at mercury- (Hg) and methylHg (MeHg)-contaminated sites. Water hyacinths (Eichhornia crassipes) were investigated for their ability to assimilate Hg and MeHg into plant biomass, in both aquatic and sediment-associated forms, over a 68-day hydropo...

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Bibliographic Details
Published in:International journal of phytoremediation 2012-02, Vol.14 (2), p.142-161
Main Authors: Chattopadhyay, Sandip, Fimmen, Ryan L, Yates, Brian J, Lal, Vivek, Randall, Paul
Format: Article
Language:English
Subjects:
Aquatic plants
Biodegradation, Environmental
Biological Transport
Biomass
Bioremediation
Contaminated sediments
Contamination
Eichhornia - drug effects
Eichhornia - metabolism
Eichhornia - radiation effects
Eichhornia crassipes
Environmental Monitoring
Geologic Sediments - chemistry
Hydroponics
leaves
Light
light intensity
macrophytes
Mercury
Mercury - metabolism
methylHg
Methylmercury Compounds - metabolism
Phosphates
Phosphates - pharmacology
Phytoremediation
Plant Roots - drug effects
Plant Roots - metabolism
Plant Roots - radiation effects
Plant Shoots - drug effects
Plant Shoots - metabolism
Plant Shoots - radiation effects
Plants (organisms)
Roots
Sediments
shoots
sustainable remediation
Uptakes
water hyacinth
Water Pollutants, Chemical - metabolism
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Summary:Phytoremediation has the potential for implementation at mercury- (Hg) and methylHg (MeHg)-contaminated sites. Water hyacinths (Eichhornia crassipes) were investigated for their ability to assimilate Hg and MeHg into plant biomass, in both aquatic and sediment-associated forms, over a 68-day hydroponic study. The suitability of E. crassipes to assimilate both Hg and MeHg was evaluated under differing phosphate (PO₄) concentrations, light intensities, and sediment:aqueous phase contamination ratios. Because aquatic rhizospheres have the ability to enhance MeHg formation, the level of MeHg in water, sediment, and water hyacinth was also measured.Hg and MeHg were found to concentrate preferentially in the roots of E. crassipes with little translocation to the shoots or leaves of the plant, a result consistent with studies from similar macrophytes. Sediments were found to be the major sink for Hg as they were able to sequester Hg, making it non-bioavailable for water hyacinth uptake. An optimum PO₄ concentration was observed for Hg and MeHg uptake. Increasing light intensity served to enhance the translocation of both Hg and MeHg from roots to shoots. Assimilation of Hg and MeHg into the biomass of water hyacinths represents a potential means for sustainable remediation of contaminated waters and sediments under the appropriate conditions.
ISSN:1549-7879
1522-6514
1549-7879
DOI:10.1080/15226514.2010.525557