Abstract
Hydrated excess protons under hydrophobic confinement are a critical component of charge transport behavior and reactivity in nanoporous materials and biomolecular systems. Herein, excess proton confinement effects are computationally investigated for sub-2 nm hydrophobic nanopores by varying the diameters (d = 0.81, 0.95, 1.09, 1.22, 1.36, 1.63, and 1.90 nm), lengths (l ∼3 and ∼5 nm), curvature, and chirality of cylindrical carbon nanotube (CNT) nanopores. CNTs with a combination of different diameter segments are also explored. The spatial distribution of water molecules under confinement is diameter-dependent; however, proton solvation and transport are consistently found to occur in the water layer adjacent to the pore wall, showing an "amphiphilic"character of the hydrated excess proton hydronium-like structure. The proton transport free energy barrier also decreases significantly as the nanopore diameter increases and proton transport becomes almost barrierless in the d > 1 nm nanopores. Among the nanopores studied, the Zundel cation (H5O2+) is populated only in the d = 0.95 nm CNT (7,7) nanopore. The presence of the hydrated excess proton and K+ inside the CNT (7,7) nanopore induces a water density increase by 40 and 20%, respectively. The K+ transport through CNT nanopores is also consistently higher in the free energy barrier than proton transport. Interestingly, the evolution of excess protonic charge defect distribution reveals a "frozen"single water wire configuration in the d = 0.81 nm CNT (6,6) nanopore (or segment), through which hydrated excess protons can only shuttle via the Grotthuss mechanism. Vehicular diffusion becomes relevant to proton transport in the "flat"free energy regions and in the wider nanopores, where protons do not primarily shuttle in the axial direction.
Original language | English |
---|---|
Pages (from-to) | 16186-16201 |
Number of pages | 16 |
Journal | Journal of Physical Chemistry C |
Volume | 124 |
Issue number | 29 |
DOIs | |
State | Published - Jul 23 2020 |
Externally published | Yes |
Funding
This work was supported as part of the Center for Advanced Materials for Energy Water Systems (AMEWS), an Energy Frontier Research Center funded by the U.S. Department of Energy (DOE), Office of Science, Basic Energy Sciences (BES). The authors gratefully acknowledge the computational resources provided in the Midway cluster operated by the University of Chicago Research Computing Center. We thank Dr. Yuxing Peng for discussions on the simulations.
Funders | Funder number |
---|---|
U.S. Department of Energy | |
Office of Science | |
Basic Energy Sciences |