| Article ID | Journal | Published Year | Pages | File Type |
|---|---|---|---|---|
| 5751056 | Science of The Total Environment | 2017 | 10 Pages |
â¢Arsenic accumulation in rice poses a human health risk.â¢A large scale analysis across Bangladesh to determine soil arsenic concentrationâ¢Soils from Holocene floodplains have higher soil arsenic concentrations.â¢Paddy soils have elevated arsenic concentration compared to non-paddy soils.â¢Surface water irrigated soils have lower arsenic compared groundwater irrigated soils.
While the impact of arsenic in irrigated agriculture has become a major environmental concern in Bangladesh, to date there is still a limited understanding of arsenic in Bangladeshi paddy soils at a landscape level. A soil survey was conducted across ten different physiographic regions of Bangladesh, which encompassed six types of geomorphology (Bil, Brahmaputra floodplain, Ganges floodplain, Meghna floodplain, Karatoya-Bangali floodplain and Pleistocene terrace). A total of 1209 paddy soils and 235 matched non-paddy soils were collected. The source of irrigation water (groundwater and surface water) was also recorded. The concentrations of arsenic and sixteen other elements were determined in the soil samples. The concentration of arsenic was higher in paddy soils compared to non-paddy soils, with soils irrigated with groundwater being higher in arsenic than those irrigated with surface water. There was a clear difference between the Holocene floodplains and the Pleistocene terraces, with Holocene floodplain soils being higher in arsenic and other elements. The results suggest that arsenic is most likely associated with less well weathered/leached soils, suggesting it is either due to the geological newness of Holocene sediments or differences between the sources of sediments, which gives rise to the arsenic problems in Bangladeshi soils.
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