TY - JOUR
T1 - Coprecipitation of phosphate and silicate affects environmental iron (oxyhydr)oxide transformations
T2 - A gel-based diffusive sampler approach
AU - Kraal, Peter
AU - van Genuchten, Case M.
AU - Lenstra, Wytze K.
AU - Behrends, Thilo
N1 - Funding Information:
C.M.v.G. acknowledges NWO Veni grant 14400. W.K.L. acknowledges support through NWO-Vici Grant (865.13.005). The authors are grateful for the technical support and advice of Dipanjan Banerjee at the DUBBLE beamline during Fe K-edge EXAFS data collection. Anton Tramper, José Mogollón, Nikki Dijkstra, Simon Müller, and Silvia Hidalgo-Martinez assisted with field work in the Oosterschelde estuary. Simon Müller and Karel As kindly assisted with data collection at ESRF. The authors gratefully acknowledge the insightful and constructive feedback from three anonymous reviewers that greatly increased the quality of this article.
Funding Information:
This work was funded by a grant from the Dutch Research Council, NWO Veni grant 863.14.014, to P.K. This work was further supported by NWO DUBBLE grant 195.068.1039 for ESRF beamline BM26A.
Publisher Copyright:
Copyright © 2020 American Chemical Society.
PY - 2020/10/6
Y1 - 2020/10/6
N2 - Sorption of nutrients such as phosphate (P) and silicate (Si) by ferric iron (oxyhydr)oxides (FeOx) modulates nutrient mobility and alters the structure and reactivity of the FeOx. We investigated the impact of these interactions on FeOx transformations using a novel approach with samplers containing synthetic FeOx embedded in diffusive hydrogels. The FeOx were prepared by Fe(III) hydrolysis and Fe(II) oxidation, in the absence and presence of P or Si. Coprecipitation of P or Si during synthesis altered the structure of Fe precipitates and, in the case of Fe(II) oxidation, lepidocrocite was (partly) substituted by poorly ordered FeOx. The pure and P- or Si-bearing FeOx were deployed in (i) freshwater sediment rich in dissolved Fe(II) and P and (ii) marine sediment with sulfidic pore water. Iron(II)-catalyzed crystallization of poorly ordered FeOx was negligible, likely due to surface passivation by adsorption of dissolved P. Reaction with dissolved sulfide was modulated by diffusion limitations and therefore the extent of sulfidation was the lowest for poorly ordered FeOx with high reactivity toward sulfide that created temporary, local sulfide depletion (Fh < Lp). We show that coprecipitation-induced changes in the FeOx structure affect coupled iron-nutrient cycling in aquatic ecosystems. The gel-based method enriches our geochemical toolbox by enabling detailed characterization of target phases under natural conditions.
AB - Sorption of nutrients such as phosphate (P) and silicate (Si) by ferric iron (oxyhydr)oxides (FeOx) modulates nutrient mobility and alters the structure and reactivity of the FeOx. We investigated the impact of these interactions on FeOx transformations using a novel approach with samplers containing synthetic FeOx embedded in diffusive hydrogels. The FeOx were prepared by Fe(III) hydrolysis and Fe(II) oxidation, in the absence and presence of P or Si. Coprecipitation of P or Si during synthesis altered the structure of Fe precipitates and, in the case of Fe(II) oxidation, lepidocrocite was (partly) substituted by poorly ordered FeOx. The pure and P- or Si-bearing FeOx were deployed in (i) freshwater sediment rich in dissolved Fe(II) and P and (ii) marine sediment with sulfidic pore water. Iron(II)-catalyzed crystallization of poorly ordered FeOx was negligible, likely due to surface passivation by adsorption of dissolved P. Reaction with dissolved sulfide was modulated by diffusion limitations and therefore the extent of sulfidation was the lowest for poorly ordered FeOx with high reactivity toward sulfide that created temporary, local sulfide depletion (Fh < Lp). We show that coprecipitation-induced changes in the FeOx structure affect coupled iron-nutrient cycling in aquatic ecosystems. The gel-based method enriches our geochemical toolbox by enabling detailed characterization of target phases under natural conditions.
UR - http://www.scopus.com/inward/record.url?scp=85092681432&partnerID=8YFLogxK
U2 - 10.1021/acs.est.0c02352
DO - 10.1021/acs.est.0c02352
M3 - Article
C2 - 32885962
AN - SCOPUS:85092681432
SN - 0013-936X
VL - 54
SP - 12795
EP - 12802
JO - Environmental Science and Technology
JF - Environmental Science and Technology
IS - 19
ER -