Formation and transformation of a short range ordered iron carbonate precursor

Knud Dideriksen; Cathrine Frandsen; Nicolas Emile Bovet; Adam F. Wallace; Ozlem Sel; Tyler Arbour; Alexandra Navrotsky; James J. De Yoreo; Jillian F. Banfield

doi:10.1016/j.gca.2015.05.005

Formation and transformation of a short range ordered iron carbonate precursor

Knud Dideriksen^*, Cathrine Frandsen, Nicolas Emile Bovet, Adam F. Wallace, Ozlem Sel, Tyler Arbour, Alexandra Navrotsky, James J. De Yoreo, Jillian F. Banfield

^*Corresponding author for this work

Department of Chemistry

24 Citations (Scopus)

Abstract

Fe(II)-carbonates, such as siderite, form in environments where O<inf>2</inf> is scarce, e.g., during marine sediment diagenesis, corrosion and possibly CO<inf>2</inf> sequestration, but little is known about their formation pathways. We show that early precipitates from carbonate solutions containing 0.1M Fe(II) with varying pH produced broad peaks in X-ray diffraction and contained dominantly Fe and CO<inf>3</inf> when probed with X-ray photoelectron spectroscopy. Reduced pair distribution function (PDF) analysis shows only peaks corresponding to interatomic distances below 15Å, reflecting a material with no long range structural order. Moreover, PDF peak positions differ from those for known iron carbonates and hydroxides. Mössbauer spectra also deviate from those expected for known iron carbonates and suggest a less crystalline structure. These data show that a previously unidentified iron carbonate precursor phase formed. Its coherent scattering domains determined from PDF analysis are slightly larger than for amorphous calcium carbonate, suggesting that the precursor could be nanocrystalline. Replica exchange molecular dynamics simulations of Fe-carbonate polynuclear complexes yield PDF peak positions that agree well with those from experiments, offering the possibility that the material is a condensate of such complexes, assembled in a relatively unorganised fashion. If this is the case, the material could be nearly amorphous, rather than being composed of well defined nanocrystals. PDF measurements of samples ageing in solution coupled with refinement with the software PDFgui show that the material transforms to siderite or siderite/chukanovite mixtures within hours and that the transformation rate depends on pH. The identified Fe-carbonate precursor may potentially form during anaerobic corrosion or bacterial Fe reduction.

Original language	English
Journal	Geochimica et Cosmochimica Acta
Volume	164
Pages (from-to)	94-109
Number of pages	16
ISSN	0016-7037
DOIs	https://doi.org/10.1016/j.gca.2015.05.005
Publication status	Published - 2015

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title = "Formation and transformation of a short range ordered iron carbonate precursor",

abstract = "Fe(II)-carbonates, such as siderite, form in environments where O2 is scarce, e.g., during marine sediment diagenesis, corrosion and possibly CO2 sequestration, but little is known about their formation pathways. We show that early precipitates from carbonate solutions containing 0.1M Fe(II) with varying pH produced broad peaks in X-ray diffraction and contained dominantly Fe and CO3 when probed with X-ray photoelectron spectroscopy. Reduced pair distribution function (PDF) analysis shows only peaks corresponding to interatomic distances below 15{\AA}, reflecting a material with no long range structural order. Moreover, PDF peak positions differ from those for known iron carbonates and hydroxides. M{\"o}ssbauer spectra also deviate from those expected for known iron carbonates and suggest a less crystalline structure. These data show that a previously unidentified iron carbonate precursor phase formed. Its coherent scattering domains determined from PDF analysis are slightly larger than for amorphous calcium carbonate, suggesting that the precursor could be nanocrystalline. Replica exchange molecular dynamics simulations of Fe-carbonate polynuclear complexes yield PDF peak positions that agree well with those from experiments, offering the possibility that the material is a condensate of such complexes, assembled in a relatively unorganised fashion. If this is the case, the material could be nearly amorphous, rather than being composed of well defined nanocrystals. PDF measurements of samples ageing in solution coupled with refinement with the software PDFgui show that the material transforms to siderite or siderite/chukanovite mixtures within hours and that the transformation rate depends on pH. The identified Fe-carbonate precursor may potentially form during anaerobic corrosion or bacterial Fe reduction.",

author = "Knud Dideriksen and Cathrine Frandsen and Bovet, {Nicolas Emile} and Wallace, {Adam F.} and Ozlem Sel and Tyler Arbour and Alexandra Navrotsky and {De Yoreo}, {James J.} and Banfield, {Jillian F.}",

year = "2015",

doi = "10.1016/j.gca.2015.05.005",

language = "English",

volume = "164",

pages = "94--109",

journal = "Geochimica et Cosmochimica Acta",

issn = "0016-7037",

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TY - JOUR

T1 - Formation and transformation of a short range ordered iron carbonate precursor

AU - Dideriksen, Knud

AU - Frandsen, Cathrine

AU - Bovet, Nicolas Emile

AU - Wallace, Adam F.

AU - Sel, Ozlem

AU - Arbour, Tyler

AU - Navrotsky, Alexandra

AU - De Yoreo, James J.

AU - Banfield, Jillian F.

PY - 2015

Y1 - 2015

N2 - Fe(II)-carbonates, such as siderite, form in environments where O2 is scarce, e.g., during marine sediment diagenesis, corrosion and possibly CO2 sequestration, but little is known about their formation pathways. We show that early precipitates from carbonate solutions containing 0.1M Fe(II) with varying pH produced broad peaks in X-ray diffraction and contained dominantly Fe and CO3 when probed with X-ray photoelectron spectroscopy. Reduced pair distribution function (PDF) analysis shows only peaks corresponding to interatomic distances below 15Å, reflecting a material with no long range structural order. Moreover, PDF peak positions differ from those for known iron carbonates and hydroxides. Mössbauer spectra also deviate from those expected for known iron carbonates and suggest a less crystalline structure. These data show that a previously unidentified iron carbonate precursor phase formed. Its coherent scattering domains determined from PDF analysis are slightly larger than for amorphous calcium carbonate, suggesting that the precursor could be nanocrystalline. Replica exchange molecular dynamics simulations of Fe-carbonate polynuclear complexes yield PDF peak positions that agree well with those from experiments, offering the possibility that the material is a condensate of such complexes, assembled in a relatively unorganised fashion. If this is the case, the material could be nearly amorphous, rather than being composed of well defined nanocrystals. PDF measurements of samples ageing in solution coupled with refinement with the software PDFgui show that the material transforms to siderite or siderite/chukanovite mixtures within hours and that the transformation rate depends on pH. The identified Fe-carbonate precursor may potentially form during anaerobic corrosion or bacterial Fe reduction.

AB - Fe(II)-carbonates, such as siderite, form in environments where O2 is scarce, e.g., during marine sediment diagenesis, corrosion and possibly CO2 sequestration, but little is known about their formation pathways. We show that early precipitates from carbonate solutions containing 0.1M Fe(II) with varying pH produced broad peaks in X-ray diffraction and contained dominantly Fe and CO3 when probed with X-ray photoelectron spectroscopy. Reduced pair distribution function (PDF) analysis shows only peaks corresponding to interatomic distances below 15Å, reflecting a material with no long range structural order. Moreover, PDF peak positions differ from those for known iron carbonates and hydroxides. Mössbauer spectra also deviate from those expected for known iron carbonates and suggest a less crystalline structure. These data show that a previously unidentified iron carbonate precursor phase formed. Its coherent scattering domains determined from PDF analysis are slightly larger than for amorphous calcium carbonate, suggesting that the precursor could be nanocrystalline. Replica exchange molecular dynamics simulations of Fe-carbonate polynuclear complexes yield PDF peak positions that agree well with those from experiments, offering the possibility that the material is a condensate of such complexes, assembled in a relatively unorganised fashion. If this is the case, the material could be nearly amorphous, rather than being composed of well defined nanocrystals. PDF measurements of samples ageing in solution coupled with refinement with the software PDFgui show that the material transforms to siderite or siderite/chukanovite mixtures within hours and that the transformation rate depends on pH. The identified Fe-carbonate precursor may potentially form during anaerobic corrosion or bacterial Fe reduction.

U2 - 10.1016/j.gca.2015.05.005

DO - 10.1016/j.gca.2015.05.005

M3 - Journal article

AN - SCOPUS:84930225696

SN - 0016-7037

VL - 164

SP - 94

EP - 109

JO - Geochimica et Cosmochimica Acta

JF - Geochimica et Cosmochimica Acta

ER -

Formation and transformation of a short range ordered iron carbonate precursor

Abstract

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