3.9 Article

Cation Exchange in Smectites as a New Approach to Mineral Carbonation

Journal

FRONTIERS IN CLIMATE
Volume 4, Issue -, Pages -

Publisher

FRONTIERS MEDIA SA
DOI: 10.3389/fclim.2022.913632

Keywords

carbon sequestration; mineral carbonation; saponite; cation exchange; kimberlite; smectite

Funding

  1. De Beers Group Services
  2. Natural Resources Canada Clean Growth Program
  3. Natural Sciences and Engineering Research Council of Canada Discovery program
  4. Canada Research Chairs program
  5. Mitacs Accelerate
  6. DOE Office of Science by Argonne National Laboratory [DE-AC02-06CH11357]
  7. National Science Foundation - Earth Sciences [EAR-1634415]
  8. U.S. Department of Energy, Geosciences [DE-FG02-94ER14466]

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Mineral carbonation of alkaline mine residues is a carbon dioxide removal strategy that can be employed by the mining industry. This study examines the mineralogy and reactivity of kimberlites and kimberlite ore from diamond mines in South Africa and Canada, and finds that the smectite phase within these rocks is highly reactive and can be used as a source of magnesium and calcium for carbonation reactions. This research suggests that smectites could be used as an alternative to highly reactive minerals in the mineral carbonation process, including in tailings from smectite-rich sediment-hosted metal deposits and oil sands tailings.
Mineral carbonation of alkaline mine residues is a carbon dioxide removal (CDR) strategy that can be employed by the mining industry. Here, we describe the mineralogy and reactivity of processed kimberlites and kimberlite ore from Venetia (South Africa) and Gahcho Kue (Canada) diamond mines, which are smectite-rich (2.3-44.1 wt.%). Whereas, serpentines, olivines, hydrotalcites and brucite have been traditionally used for mineral carbonation, little is known about the reactivity of smectites to CO2. The smectite from both mines is distributed as a fine-matrix and is saponite, Mm+ Mg-x/m(3)(AlxSi4-x)O-10(OH)(2)center dot nH(2)O, where the layer charge deficiency is balanced by labile, hydrated interlayer cations (Mm+). A positive correlation between cation exchange capacity and saponite content indicates that smectite is the most reactive phase within these ultramafic rocks and that it can be used as a source of labile Mg2+ and Ca2+ for carbonation reactions. Our work shows that smectites provide the fast reactivity of kimberlite to CO2 in the absence of the highly reactive mineral brucite [Mg(OH)(2)]. It opens up the possibility of using other, previously inaccessible rock types for mineral carbonation including tailings from smectite-rich sediment-hosted metal deposits and oil sands tailings. We present a decision tree for accelerated mineral carbonation at mines based on this revised understanding of mineralogical controls on carbonation potential.

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