Fe(II)(aq) uptake of Mg(II)–Al(III)/Fe(III)–SO4/CO3 HTLCs under alkaline conditions: adsorption and solid state transformation mechanisms

Mario A. Gomez; M. Jim Hendry; Samir Elouatik; Joseph Essilfie-Dughan; Susanta Paikaray

doi:10.1039/C4RA08802F

Fe(ii)_(aq) uptake of Mg(ii)–Al(iii)/Fe(iii)–SO₄/CO₃ HTLCs under alkaline conditions: adsorption and solid state transformation mechanisms†

Mario A. Gomez,*^a M. Jim Hendry,^a Samir Elouatik,^b Joseph Essilfie-Dughan^a and Susanta Paikaray^b

* Corresponding authors

^a Department of Geological Sciences, University of Saskatchewan, 114 Science Place, Saskatoon, Saskatchewan, Canada
E-mail: mag346@mail.usask.ca
Tel: +1-306-2616246

^b Department of Chemistry, University of Montreal, C.P. 6128, Succursale Centre-ville, Montreal, Quebec, Canada

Abstract

Abiotic reduction of Mg(II)–Al(III)/Fe(III)–SO₄/CO₃ hydrotalcites (HTLCs) was investigated under three anoxic abiotic reaction conditions: (1) a target pH of 8 and 10 mM Fe(II)_(aq), (2) a target pH of 8 and 0.5 mM Fe(II)_(aq), and (3) a target pH of 10 and 0.5 mM Fe(II)_(aq). Under both Fe(II)_(aq) concentrations and at the targeted pH of 8, the greatest Fe(II)_(aq) uptake, Mg(II)_(aq) release, and least deviation in pH was observed for Fe-based HTLCs (Mg(II)–Fe(III)–SO₄/CO₃) irrespective of the interlayer ion (SO₄ or CO₃). In contrast, the Al-based HTLCs showed the greatest pH drift from the target pH of 8; this phenomenon was attributed to the remaining total Fe(II + III) in solution. At the target pH of 10 and 0.5 mM Fe(II)_(aq), the pH of the Al-based HTLCs was greater than the Fe-based HTLCs despite 99% of the Fe(II) being removed from solution in both cases. The greatest Mg(II)_(aq) release was again observed for the Fe-based HTLCs. Unique to these reaction conditions was the readsorption of the released Mg(II)_(aq) by the Mg–Fe–CO₃ HTLC. The major reaction phases produced from the adsorption of Fe(II)_(aq) onto Mg(II)–Al(III)/Fe(III)–SO₄/CO₃ HTLCs were green rust (GR) and magnetite (MG). Two types of phase transformation mechanisms are suggested to occur during the adsorption of Fe(II)_(aq) onto Mg(II)–Al(III)/Fe(III)–SO₄/CO₃ HTLCs, both dependent upon the metal ion (Al vs. Fe) and independent of the interlayer ions (SO₄ or CO₃). For Fe-based HTLCs (Mg–Fe–SO₄/CO₃), surface adsorption of Fe(II)_(aq) and surface precipitation allows electron transfer (between Fe(II) ↔ Fe(III)) and subsequent atom exchange to occur at the surface as well as within the bulk HTLC structure. For the Al-based HTLCs (Mg–Al–SO₄/CO₃), this surface adsorption of Fe(II)_(aq) and surface precipitation still occurs but electron transfer is limited to the precipitated surface phase due to the redox inactivity of the Al(III) groups in the HTLC structure.

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Article information

DOI: https://doi.org/10.1039/C4RA08802F
Article type: Paper
Submitted: 17 Aug 2014
Accepted: 17 Oct 2014
First published: 17 Oct 2014

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RSC Adv., 2014,4, 54973-54988

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Fe(II)_(aq) uptake of Mg(II)–Al(III)/Fe(III)–SO₄/CO₃ HTLCs under alkaline conditions: adsorption and solid state transformation mechanisms

M. A. Gomez, M. J. Hendry, S. Elouatik, J. Essilfie-Dughan and S. Paikaray, RSC Adv., 2014, 4, 54973 DOI: 10.1039/C4RA08802F

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