Insights into the Chemical Mechanism for CO 2 (aq) and H + in Aqueous Diamine Solutions - An Experimental Stopped-Flow Kinetic and 1 H/ 13 C NMR Study of Aqueous Solutions of N,N-Dimethylethylenediamine for Postcombustion CO 2 Capture.

In an effort to advance the understanding of multiamine based CO2 capture process absorbents, we report here the determination of the kinetic and equilibrium constants for a simple linear diamine N,N-dimethylethylenediamine (DMEDA) via stopped-flow spectrophotometric kinetic measurements and1 H/13 C NMR titrations at 25.0 °C. From the kinetic data, the formation of monocarbamic acid (DMEDACOOH) from the reaction of DMEDA with CO2 (aq) is the dominant reaction at high pH > 9.0 (k7 = 6.99 × 103 M-1 ·s-1 ). Below this pH, the formation of protonated monocarbamic acid (DMEDACOOH2 ) via the pathway involving DMEDAH+ and CO2 (aq) becomes active and contributes to the kinetics despite the 107-fold decrease in the rate constant between the two pathways.1 H and13 C NMR spectra as a function of decreasing pH (increasing HCl concentration) at 25.0 °C have been evaluated here to confirm the protonation events in DMEDA. Calculations of the respective DMEDA nitrogen partial charges have also been undertaken to support the NMR protonation study. A comparison of the DMEDA kinetic constants with the corresponding data for piperazine (PZ) reveals that despite the larger basicity of DMEDA, the enhanced and superior kinetic performance of PZ with CO2 (aq) above its predicted Bronsted reactivity is not observed in DMEDA.