Here, we estimate global CO₂ mitigation potentials facilitated by CO₂ mineralization and utilization as a result of accelerated carbonation using various types of alkaline solid wastes in different regions of the world.

Fig. 1: Estimates of global CO₂ reduction by mineralization and utilization using alkaline solid wastes.

Technology Overview
We find that a substantial amount of CO₂ (that is, 4.02 Gt per year) could be directly fixed and indirectly avoided by CO₂ mineralization and utilization, corresponding to a reduction in global anthropogenic CO₂ emissions of 12.5%. In particular, China exhibits the greatest potential worldwide to implement CO₂ mineralization and utilization, where it would account for a notable reduction of up to 19.2% of China’s annual total emissions.

Applications & Benefits
Our study reveals that CO₂ mineralization and utilization using alkaline solid wastes should be regarded as one of the essential green technologies in the portfolio of strategic global CO₂ mitigation.

Abstract：
CO₂ mineralization and utilization using alkaline solid wastes has been rapidly developed over the last ten years and is considered one of the promising technologies to stabilize solid wastes while combating global warming. Despite the publication of a number of reports evaluating the performance of the processes, no study on the estimation of the global CO₂ reduction potential by CO₂ mineralization and utilization using alkaline solid wastes has been reported. Here, we estimate global CO₂ mitigation potentials facilitated by CO₂ mineralization and utilization as a result of accelerated carbonation using various types of alkaline solid wastes in different regions of the world. We find that a substantial amount of CO₂ (that is, 4.02 Gt per year) could be directly fixed and indirectly avoided by CO₂ mineralization and utilization, corresponding to a reduction in global anthropogenic CO₂ emissions of 12.5%. In particular, China exhibits the greatest potential worldwide to implement CO₂ mineralization and utilization, where it would account for a notable reduction of up to 19.2% of China’s annual total emissions. Our study reveals that CO₂ mineralization and utilization using alkaline solid wastes should be regarded as one of the essential green technologies in the portfolio of strategic global CO₂ mitigation.

CO₂ mineralization and utilization by alkaline solid wastes for potential carbon reduction
Author：Pan S.-Y., Chen Y.-H., Fan L.-S., Kim H., Gao X., Ling T.-C., Chiang P.-C., Pei S.-L., Gu G.
Year：2020
Source publication：Nature Sustainability volume 3, p.399–405 (2020)
Subfield Highest percentage：99%    Geography, Planning and Development    #2/704

https://www.nature.com/articles/s41893-020-0486-9