Unveiling the impact of exposed mineral facets on chromium repartitioning in aging lepidocrocite

As a typical intermediate product of metastable iron oxide phase transformation, lepidocrocite is a critical player in migrating and transforming heavy metals (HMs) in soils and sediments. However, the repartitioning behavior of its associated HMs during the aging of lepidocrocite is not fully under...

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Published in:The Science of the total environment 2024-12, Vol.955, p.177268, Article 177268
Main Authors: Li, Xiaofei, Guo, Chuling, Jin, Xiaohu, Yao, Qian, Bao, Yanping, Jiang, Xueding, Lu, Guining, Pillai, Suresh C., Wang, Hailong, Dang, Zhi
Format: Article
Language:English
Subjects:
Chromate
chromium
Divergent repartitioning
environment
Facet dependent
goethite
hematite
intermediate product
Lepidocrocite
Phase transformation
phase transition
temperature
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Summary:As a typical intermediate product of metastable iron oxide phase transformation, lepidocrocite is a critical player in migrating and transforming heavy metals (HMs) in soils and sediments. However, the repartitioning behavior of its associated HMs during the aging of lepidocrocite is not fully understood. We investigated the phase transformation of Cr(VI)-lepidocrocite with different exposed facets at various aging conditions (pH: 7 and 10; temperature: 25 °C and 75 °C). The results indicated that the phase transformation of lepidocrocite is facet-dependent. The rod-like lepidocrocite (R-LEP), characterized by a high ratio of (001)/(010) facets, demonstrated significant structural stability, with only minimal transformation to goethite observed over 9 days. In contrast, the dominant (010) facet in plate-like lepidocrocite (P-LEP) directly underwent the phase transformation from lepidocrocite to hematite. Meanwhile, the coordination of Cr(VI) onto the facets of lepidocrocite notably strengthened the resistance to its phase transformation. Specifically, the interaction between Cr(VI) and the (001) facets was particularly effective in inhibiting the phase transformation of lepidocrocite. In addition, the release behavior of Cr(VI) also showed lepidocrocite facet dependence. For instance, at pH = 7 and 75 °C, the release percentage of Cr(VI) on P-LEP reached up to 81 %, 1.7 times that of the release on R-LEP (46.7 %). Moreover, more non-extractable Cr speciation in P-LEP transformed into aqueous speciation and was partially redistributed on hematite. These findings provide novel insights into the role that the mineral exposed facets play in regulating the environmental behavior of Cr during the iron oxide phase transformation. [Display omitted] •Lepidocrocite with a high (001) facet exposure retard its transformation.•Cr(VI) interacts with the (001) facet and inhibits lepidocrocite transformation.•Lepidocrocite with a high (010) facet exposure increases Cr(VI) release.•Adsorbed Cr on lepidocrocite can be partially redistributed onto hematite.
ISSN:0048-9697
1879-1026
1879-1026
DOI:10.1016/j.scitotenv.2024.177268