Formation of magnesite and hydromagnesite from direct aqueous carbonation of thermally activated lizardite

Formation of magnesite and hydromagnesite from direct aqueous carbonation of thermally activated lizardite

This work examines factors, which can influence the formation of magnesium (Mg) carbonate phases produced during direct aqueous carbonation of heat‐activated lizardite, hydromagnesite, and the targeted magnesite phase. Carbon dioxide mass transfer and mixing during the course of the reaction was exa...

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Veröffentlicht in:Environmental progress 2019-05, Vol.38 (3), p.n/a
Hauptverfasser: Abu Fara, Ammar, Rayson, Mark R., Brent, Geoff F., Oliver, Timothy K., Stockenhuber, Michael, Kennedy, Eric M.
Format: Artikel
Sprache:eng
Schlagworte:
Activated carbon
Basic magnesium carbonate
Carbon dioxide
Carbonation
hydromagnesite
Impellers
Liquid surfaces
lizardite
Magnesite
Magnesium
Magnesium carbonate
Mass transfer
Reactor design
Reactors
Stirring
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container_issue 3
container_start_page
container_title Environmental progress
container_volume 38
creator Abu Fara, Ammar
Rayson, Mark R.
Brent, Geoff F.
Oliver, Timothy K.
Stockenhuber, Michael
Kennedy, Eric M.
description This work examines factors, which can influence the formation of magnesium (Mg) carbonate phases produced during direct aqueous carbonation of heat‐activated lizardite, hydromagnesite, and the targeted magnesite phase. Carbon dioxide mass transfer and mixing during the course of the reaction was examined by varying impeller positioning and stirring speed of the dual impeller reactor. From a practical perspective, this provides some insight into the importance of reactor design, to achieve the highest possible magnesite yield. At the lowest stirring speed studied (100 rpm), two Mg‐carbonate phases were observed in all samples. By simply increasing the stirring speed, hydromagnesite was observed only during the initial stages of reaction and magnesite formation dominated thereafter. Higher yields of carbonate were obtained for the intermediate and maximum stirring speeds (450 and 600 rpm), respectively. Positioning of the uppermost impeller near to the liquid surface was also found to favor the formation of magnesite. Thermodynamic simulations (using OLIAnalyzer 9.2) were in a good agreement with the experimental results.
doi_str_mv 10.1002/ep.13244
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subjects Activated carbon
Basic magnesium carbonate
Carbon dioxide
Carbonation
hydromagnesite
Impellers
Liquid surfaces
lizardite
Magnesite
Magnesium
Magnesium carbonate
Mass transfer
Reactor design
Reactors
Stirring
title Formation of magnesite and hydromagnesite from direct aqueous carbonation of thermally activated lizardite
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