<p>Mineralizing CO<sub>2</sub> in alkaline construction materials can reduce process emissions. This study measures the effect of carbonic anhydrase on CO<sub>2</sub> uptake and retention in hydrated lime, Portland cement, fly ash, and slag under ambient conditions using a mass-flow-controlled CO<sub>2</sub> supply and gravimetric tracking. CO<sub>2</sub> was supplied for 1440&#xa0;min for hydrated lime and cement and for 360&#xa0;min for fly ash and slag, then stopped to quantify permanently retained mass. Carbonic anhydrase increased total CO<sub>2</sub> uptake across all materials by 71 to 89 percent. Hydrated lime reached 474.1&#xa0;mg g<sup>−1</sup> with the enzyme. Cement reached 285.9&#xa0;mg g<sup>−1</sup>. Fly ash and slag reached 308.3&#xa0;mg g<sup>−1</sup> and 312.4&#xa0;mg g<sup>−1</sup>. The fraction retained after cutoff increased for all solids and was nearly complete in several enzyme cases, while water controls showed negligible permanence. Enzyme reuse over four cycles retained 87.9 percent of the initial performance. The data support a surface-coupled mechanism in which the enzyme accelerates CO<sub>2</sub> hydration in the particle boundary layer, increases local carbonate availability, and drives precipitation with Ca<sup>2+</sup> and Mg<sup>2+</sup> on solid surfaces. The reaction endpoint remains unchanged; only the rate is altered. These results define material-enzyme combinations and operating conditions for enzyme-assisted mineralization in construction-relevant systems.</p>

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Enzyme assisted carbon dioxide capture and mineralization in construction relevant alkaline materials

  • Nabeel Liaqat,
  • Xiong Bill Yu

摘要

Mineralizing CO2 in alkaline construction materials can reduce process emissions. This study measures the effect of carbonic anhydrase on CO2 uptake and retention in hydrated lime, Portland cement, fly ash, and slag under ambient conditions using a mass-flow-controlled CO2 supply and gravimetric tracking. CO2 was supplied for 1440 min for hydrated lime and cement and for 360 min for fly ash and slag, then stopped to quantify permanently retained mass. Carbonic anhydrase increased total CO2 uptake across all materials by 71 to 89 percent. Hydrated lime reached 474.1 mg g−1 with the enzyme. Cement reached 285.9 mg g−1. Fly ash and slag reached 308.3 mg g−1 and 312.4 mg g−1. The fraction retained after cutoff increased for all solids and was nearly complete in several enzyme cases, while water controls showed negligible permanence. Enzyme reuse over four cycles retained 87.9 percent of the initial performance. The data support a surface-coupled mechanism in which the enzyme accelerates CO2 hydration in the particle boundary layer, increases local carbonate availability, and drives precipitation with Ca2+ and Mg2+ on solid surfaces. The reaction endpoint remains unchanged; only the rate is altered. These results define material-enzyme combinations and operating conditions for enzyme-assisted mineralization in construction-relevant systems.