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arXiv:2405.00783v2 Announce Type: replace-cross
Abstract: Using molecular simulation and continuum dielectric theory, we consider how electrochemical kinetics are modulated as a function of twist angle in bilayer graphene electrodes. By establishing an effective connection between twist angle and the screening length of charge carriers within the electrode, we investigate how tunable metallicity can result in modified statistics of the electron transfer energy gap. Constant potential molecular simulations show that the activation free energy for electron transfer is an increasing function of the screening length, or decreasing function the density of states at the Fermi energy in the electrode, and subsequently a non-monotonic function of twist angle. We find the twist angle alters the density of states, which tunes the number of thermally-accessible channels for electron transfer, as well as the reorganization energy by altering the stability of the vertically excited state through attenuated image charge interactions. Understanding these effects allows us to cast the Marcus rate of interfacial electron transfer as a function of twist angle, in a manner consistent with a growing body of experimental observations.