Rae Brigham scite author profile

By the end of the century tens of gigatonnes of CO2 will need to be removed from the atmosphere every year to maintain global temperatures. Natural weathering of ultramafic rocks and subsequent mineralization reactions can convert atmospheric CO2 into ultra-stable carbonates. But, while natural weathering will eventually draw down all excess CO2, this process will need hundreds of thousands of years to do it. The CO2 mineralization process could be accelerated by weathering ultramafic rocks with biodegradable lixiviants like organic acids. But, in this article we show that if these lixiviants are produced from cellulosic biomass, the demand created by CO2 mineralization could monopolize the world's supply of biomass even if CO2 mineralization performance is high. In this article we demonstrate that electromicrobial production technologies that (EMP) combine renewable electricity and microbial metabolism could produce lixiviants for as little as $200 to $400 per tonne at solar electricity prices achievable within the decade. Furthermore, this allows the lixiviants needed to sequester a tonne of CO2 to produced for less than $100, even with modest CO2 mineralization performance.

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Rae Brigham

Practical and thermodynamic constraints on electromicrobially accelerated CO2 mineralization

Practical and Thermodynamic Constraints on Electromicrobially-Accelerated CO₂ Mineralization

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Rae Brigham

Practical and thermodynamic constraints on electromicrobially accelerated CO2 mineralization

Practical and Thermodynamic Constraints on Electromicrobially-Accelerated CO2 Mineralization

Contact Info

Product

Resources

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Practical and Thermodynamic Constraints on Electromicrobially-Accelerated CO₂ Mineralization