PNNL

Abstract

ABSTRACT: We present two-dimensional (2D) and three-dimensional (3D) chemical speciation of a switchable ionic liquid CO2 capture solvent to asses how these fluids facilitate CO2 transport at high solution viscosities. In this study, we use in situ liquid time-of-flight secondary ion mass spectrometry (ToF-SIMS) enabled by a vacuum-compatible microreactor. SIMS spectra show the existence of 1-((1,3-dimethylimidazolidin-2-ylidene)amino)propan-2-ol (IPADM-2-BOL) and CO2 + IPADM-2-BOL, con-firming the proposed zwitterionic CO2 binding mechanism. 2D and 3D chemical mapping showed IPADM-2-BOL exhibited a heterogeneous molecular structure, with regions of CO2-free IPADM-2-BOL coexisting with clusters of zwitterionic carbonate ions (IPADM-2-BOL + CO2). The solvent was composed of ~10–20 nm clusters of zwitterionic carbonate ions at any CO2 loading above 0%. The size of clusters was found not to grow with CO2 loading; rather, the concentration and distribution of clusters in-creased. 2D measurements also confirmed that the small clusters of bound CO2 aggregate in solution, coalescing to form >500 nm aggregates, and concurrently creating regions of unreacted solvent where CO2 can readily diffuse and immediately eact. The het-erogeneous domains introduce a trade-off between rapid CO2 diffusion and reactivity at the expense of a high solution viscosity.