Isotherm model for moisture-controlled CO2 sorption

Moisture-controlled sorption of CO2, the basis for moisture-swing CO2 capture from air, is a novel phenomenon observed in strong-base anion exchange materials. Prior research has shown that Langmuir isotherms provide an approximate fit to moisture-controlled CO2 sorption isotherm data. However, this fit still lacks a governing equation derived from an analytic model. In this paper, we derive an analytic form for an isotherm equation from a bottom-up approach, starting with a fundamental theory for an alkali liquid. In the range of interest relevant to CO2 capture from air, an isotherm equation for an alkali liquid reduces to a simple analytic form with a single parameter, K-eq. In the limit K-eq >> 1, a 2nd order approximation simplifies to a Langmuir isotherm that, however, deviates from experimental data. The isotherm theory for an alkali liquid has been generalized to a strong-base anion exchange material. In a strong-base anion exchange material, water concentration inside a sorbent, [H2O], is not large enough to be regarded as constant, which allows us to extend K-eq to K-eq(AEM)eff = K-eq(AEM) x [H2O](-n) according to the law of mass action. The final isotherm formula has been validated by experimental data from the literature. For a moisture-controlled CO2 sorbent, K-eq(AEM)eff varies significantly with moisture content of the sorbent. Depending on moisture level, the observed K-eq(AEM)eff in a specific sorbent ranges from a few times to a few thousand times the value of K-eq of a 2 mol L-1 alkali liquid.

Automated summary

This paper investigates the moisture-controlled sorption of CO2 in strong-base anion exchange materials and derives an analytic form for an isotherm equation using a bottom-up approach. The isotherm theory for an alkali liquid is generalized to a strong-base anion exchange material and the final isotherm formula is validated with experimental data. The study shows that the moisture level significantly affects the K-eq(AEM)eff value of the sorbent.