Phytoextraction of Metals from Contaminated Soil: A Review of Plant/Soil/Metal Interaction and Assessment of Pertinent Agronomic Issues

Lasat, Mitch M.

doi:10.4148/1090-7025.1015

Cited by 241 publications

(243 citation statements)

References 57 publications

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“…Also, the immobilization of elements by root adsorption may be of some importance. This mechanism avoids element's translocation from roots to shoots in some species working as a defense barrier, decreasing the phytoextraction potential of such species since only a small part of ions associated to the roots are effectively absorbed (Lasat, 2000). Silva et al (2007) used soybean and rice to evaluate the absorption and capacity of translocation of heavy metals in the same soil studied here and observed that the roots limited the translocation of copper and lead to the aerial parts of both cultures.…”

Section: Resultsmentioning

confidence: 99%

“…These indicators allowed estimating also the period of time necessary to remove all soil contamination, considering four annual cultivation cycles. Soil decontamination is considered successful when the plants are able to extract up to 1 -2% of the metal from soil (Lasat, 2000) or up to 1% of Zn and Cu, 0.6% of Pb total content from soil (Garbisu and Alkorta, 2001).…”

Section: Methodsmentioning

confidence: 99%

“…It consists in the removal of metals by plants through uptake and accumulation into biomass (Nascimento and Xing, 2006). Interestingly, phytoremediation was recognized and documented by humans more than 300 years ago, however the scientific study and development of suitable plants was not conducted until the early 1980's (Lasat, 2000).…”

Section: Introductionmentioning

confidence: 99%

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Vegetable species for phytoextraction of boron, copper, lead, manganese and zinc from contaminated soil

Santos

Rodella²,

Abreu

et al. 2010

Sci. agric. (Piracicaba, Braz.)

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Phytoremediation is an attractive option to remove metal from contaminated soil since it is a simple, low-cost, and environmentally friendly procedure. To better examine the phytoremediation potential of kenaf (Hybiscus canabinnus), mustard (Brassica juncea), turnip (Raphunus sativus) and amaranth (Amaranthus crentus) plants, a greenhouse experiment was performed in which these species were grown on a soil contaminated with Zn, Cu, Mn, Pb and B. The translocation, the bioconcentration and the removal index, the transference factor and the time to reach 50% of element removal from soil, among other indicators, were used in order to identify a hyperaccumulator. Kenaf plants were more tolerant to the conditions tested, with the highest dry matter production and no visual toxicity symptoms. Amaranth would be the species chosen to remediate the soil under field conditions as it presented the higher indexes for decontamination of Zn and Mn and was also able to remove B. Turnip showed the best results for Pb removal. All species tested were able to remove B from soil. In spite, none of the plant species tested could be characterized as a hyperaccumulator.

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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Vegetable species for phytoextraction of boron, copper, lead, manganese and zinc from contaminated soil

Santos

Rodella²,

Abreu

et al. 2010

Sci. agric. (Piracicaba, Braz.)

View full text Add to dashboard Cite

show abstract

“…Unlike organic compounds, metals cannot be degraded (Lasat, 2000). To decrease the contents and bioavailability of heavy metals usually requires their removal.…”

Section: Introductionmentioning

confidence: 99%

“…The addition of chemical immobilization amendments may only immobilize lethal levels for restricted periods of time and introduce some other chemicals. Phytoremediation is recognized as the most commercially and environmental friendly available technology (Lasat, 2000), but up to now, only a limited number of plants have been found to have the phytoaccumulation ability and much less can be used for field phytoremediation because of low biomass production.…”

Section: Introductionmentioning

confidence: 99%

Effects of earthworm activity on fertility and heavy metal bioavailability in sewage sludge

Liu

Zhang

2005

Environment International

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Rhizofiltration of a Heavy Metal (Lead) Containing Wastewater Using the Wetland Plant Carex pendula

Yadav

Siebel

Bruggen

2011

CLEAN Soil Air Water

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Research Article Rhizofiltration of a Heavy Metal (Lead) Containing Wastewater Using the Wetland Plant Carex pendulaRhizofiltration is a subset technique of phytoremediation which refers to the approach of using plant biomass for removing contaminants, primarily toxic metals, from polluted water. The effective implementation of this in situ remediation technology requires experimental as well as conceptual insight of plant-water interactions that control the extraction of targeted metal from polluted water resources. Therefore, pot and simulation experiments are used in this study to investigate the rhizofiltration of a lead containing wastewater using plants of Carex pendula, a common wetland plant found in Europe. The metal contaminant extraction along with plant growth and water uptake rates from a wastewater having varying Pb concentration is studied experimentally for 2 wk. The temporal distribution of the metal concentration in the wastewater and the accumulated metal in different compartments of C. pendula at the end are analyzed using atomic absorption spectrometry. Parameters of the metal uptake kinetics are deduced experimentally for predicting the metal removal by root biomass. Further, mass balance equations coupled with the characterized metal uptake kinetics are used for simulating the metal partitioning from the wastewater to its accumulation in the plant biomass. The simulated metal content in wastewater and plant biomass is compared with the observed data showing a good agreement with the later. Results show that C. pendula accumulates considerable amounts of lead, particularly in root biomass, and can be considered for the cleanup of lead contaminated wastewaters in combination with proper biomass disposal alternatives. Also, the findings can be used for performing further non-hydroponics experiment to mimic the real wetland conditions more closely.

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Phytoextraction of Metals from Contaminated Soil: A Review of Plant/Soil/Metal Interaction and Assessment of Pertinent Agronomic Issues

Cited by 241 publications

References 57 publications

Vegetable species for phytoextraction of boron, copper, lead, manganese and zinc from contaminated soil

Vegetable species for phytoextraction of boron, copper, lead, manganese and zinc from contaminated soil

Effects of earthworm activity on fertility and heavy metal bioavailability in sewage sludge

Rhizofiltration of a Heavy Metal (Lead) Containing Wastewater Using the Wetland Plant Carex pendula

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