Elucidating the Proton Transport Pathways in Liquid Imidazole with First-principles Molecular Dynamics.

Imidazole is a promising anhydrous proton conductor with a high conductivity comparable to that of water at a similar temperature relative to its melting point. Previous theoretical studies of the mechanism of proton transport in imidazole have relied either on empirical models or on ab initio trajectories that have been too short to draw significant conclusions. Here, we present the results of ab initio molecular dynamics simulations of an excess proton in liquid imidazole reaching 1 nanosecond in total simulation time. We find that the proton transport is dominated by structural diffusion, with the diffusion constant of the proton defect $\sim$8 times higher than the self-diffusion of the imidazole molecules. By using correlation function analysis, we decompose the mechanism for proton transport into a series of first-order processes and show that the proton transport mechanism occurs over three distinct time and length scales. Although the mechanism at intermediate times is dominated by hopping along pseudo one-dimensional chains at longer times, the overall rate of diffusion is limited by the reformation of these chains, thus providing a more complete picture of the traditional an idealized Grotthuss structural diffusion mechanism.