Predicting arsenic bioavailability to hyperaccumulator pteris vittata in arsenic-contaminated soils

Using chemical extraction to evaluate plant arsenic availability in contaminated soils is important to estimate the time frame for site cleanup during phytoremediation. It is also of great value to assess As mobility in soil and its risk in environmental contamination. In this study, four convention...

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Bibliographic Details
Published in:International journal of phytoremediation 2012-11, Vol.14 (10), p.939-949
Main Authors: Gonzaga, Maria Isidória Silva, Ma, Lena Q, Pacheco, Edson Patto, dos Santos, Wallace Melo
Format: Article
Language:English
Subjects:
ammonium sulfate
Ammonium sulfates
Arsenic
Arsenic - chemistry
Arsenic - pharmacokinetics
Arsenic content
arsenic mobility
Bioavailability
Biodegradation, Environmental
Biological Availability
Bioremediation
calcium
chemical extraction
Contamination
Correlation
Environmental cleanup
Extraction
Extraction processes
Ferns
greenhouses
Industrial Waste
magnesium
Mining
organic acids and salts
Pesticides
phytoextraction
phytoremediation
Plants (organisms)
polluted soils
pollution
prediction
Pteris - metabolism
Pteris vittata
risk
root exudates
Soil - chemistry
Soil contamination
soil organic matter
Soil Pollutants - chemistry
Soil Pollutants - pharmacokinetics
soil properties
Soils
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Summary:Using chemical extraction to evaluate plant arsenic availability in contaminated soils is important to estimate the time frame for site cleanup during phytoremediation. It is also of great value to assess As mobility in soil and its risk in environmental contamination. In this study, four conventional chemical extraction methods (water, ammonium sulfate, ammonium phosphate, and Mehlich III) and a new root-exudate based method were used to evaluate As extractability and to correlate it with As accumulation in P. vittata growing in five As-contaminated soils under greenhouse condition. The relationship between different soil properties, and As extractability and plant As accumulation was also investigated. Arsenic extractability was 4.6%, 7.0%, 18%, 21%, and 46% for water, ammonium sulfate, organic acids, ammonium phosphate, and Mehlich III, respectively. Root exudate (organic acids) solution was suitable for assessing As bioavailability (81%) in the soils while Mehlich III (31%) overestimated the amount of As taken up by plants. Soil organic matter, P and Mg concentrations were positively correlated to plant As accumulation whereas Ca concentration was negatively correlated. Further investigation is needed on the effect of Ca and Mg on As uptake by P. vittata. Moreover, additional As contaminated soils with different properties should be tested.
ISSN:1549-7879
1522-6514
1549-7879
DOI:10.1080/15226514.2011.636404