Biologically enhanced degassing and precipitation of magnesium carbonates derived from bicarbonate solutions

Oliver, Timothy K.; Dlugogorski, Bogdan Z.; Kennedy, Eric M.

Title: Biologically enhanced degassing and precipitation of magnesium carbonates derived from bicarbonate solutions
Creator: Oliver, Timothy K.; Dlugogorski, Bogdan Z.; Kennedy, Eric M.
Relation: Minerals Engineering Vol. 61, p. 113-120
Publisher Link: http://dx.doi.org/10.1016/j.mineng.2013.11.003
Publisher: Pergamon Press
Resource Type: journal article
Date: 2014
Description: This contribution reports the results of batch and semibatch experiments involving bubbling of nitrogen in aqueous solutions of magnesium bicarbonate, with and without the addition of either carbonic anhydrase (CA) or Scenedesmus alga to the solution. Precipitation of nesquehonite occurred during both an accelerated degassing of CO₂ induced by sparging small nitrogen bubbles (representative diameter of 20 µm), and during slow degassing engendered by introducing large nitrogen bubbles (representative diameter of 5 mm). The response of the system during low rates of degassing closely approached quasi-thermodynamic predictions, which permitted an estimation of the level of supersaturation of nesquehonite, prior to the onset of precipitation. Small bubbles and CA significantly increased rates of degassing and indirectly the production of nesquehonite, as the rate of degassing can limit the precipitation process. The response of the system during rapid rates of degassing, prior to precipitation, was not entirely consistent with quasi-thermodynamic predictions. During precipitation, higher rates of degassing produced similar alkalisation and precipitation trends to that observed for lower rates of degassing. Our results agree with the formation of travertine deposits in nature, where the degassing of solutions enriched with inorganic carbon, and enhanced alkalisation by microorganisms, have been shown to influence carbonate formation. The results demonstrate a catalytic effect of CA on the rate limiting carbonate reactions, increasing CO₂ exchange between nitrogen and water, and indirectly accelerating the precipitation of carbonates for a system controlled by rate of degassing. The results of this study have applications to large-scale storage of CO₂ by mineralisation.
Subject: accelerated mineral carbonation; nesquehonite precipitation; degassing; carbonic anhydrase; alkalisation
Identifier: http://hdl.handle.net/1959.13/1307053
Identifier: uon:21318
Identifier: ISSN:0892-6875
Language: eng
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