Cement clinker production in an electrolyser

20 July 2022, Version 1
This content is a preprint and has not undergone peer review at the time of posting.

Abstract

The manufacture of cement from limestone is the single largest industrial source of CO2(g) emissions into the atmosphere. We report here an electrochemical flow reactor (electrolyser) that continuously converts limestone (CaCO3(s)) into Ca(OH)2(s) at a high rate of product formation (486 mg h-1 at 100 mA cm-2). The Ca(OH)2(s) product (slaked lime) is a chemical precursor to cement clinker, the main component of Portland cement, and other cement varieties. This three-compartment electrolyser operates with ~100% current efficiency at a cell voltage of 2.9 V and generates pure O2(g), H2(g), and CO2(g) streams that can be utilized downstream without purification. To demonstrate this feature, we feed the CO2(g) released from limestone directly to a second electrolyser that valorizes CO2(g) into higher value carbon-containing products (e.g., CO). A life-cycle analysis indicates that the proposed electrochemical process can decrease CO2 emissions per tonne of cement by 75% and achieve cost-parity with incumbent cement manufacturing processes with a carbon tax of $50/tonne CO2.

Keywords

cement
CO2 utilization
electrolyser

Supplementary materials

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Title
Cement clinker production in an electrolyser - Supplementary Materials
Description
Cement clinker production in an electrolyser - Supplementary Materials
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