Abstract
We characterize the energetics and atomic structures involved in the intercalation of copper and silver into the van der Waals gap of molybdenum disulfide as well as the resulting ionic and electronic transport properties using first-principles density functional theory. The intercalation energy of systems with formula (Cu,Ag)xMoS2 decreases with ion concentration and ranges from 1.2 to 0.8 eV for Cu; Ag exhibits a stronger concentration dependence from 2.2 eV for x = 0.014 to 0.75 eV for x = 1 (using the fcc metal as a reference). Partial atomic charge analysis indicates that approximately half an electron is transferred per metallic ion in the case of Cu at low concentrations and the ionicity decreases only slightly with concentration. In contrast, while Ag is only slightly less ionic than Cu for low concentrations, charge transfer reduces significantly to approximately 0.1 e for x = 1. This difference in ionicity between Cu and Ag correlates with their intercalation energies. Importantly, the predicted values indicate the possibility of electrochemical intercalation of both Cu and Ag into MoS2 and the calculated activation energies associated with ionic transport within the gaps, 0.32 eV for Cu and 0.38 eV for Ag, indicate these materials to be good ionic conductors. Analysis of the electronic structure shows that charge transfer leads to a shift of the Fermi energy into the conduction band resulting in a semiconductor-to-metal transition. Electron transport calculations based on non-equilibrium Green's function show that the low-bias conductance increases with metal concentration and is comparable in the horizontal and vertical transport directions. These properties make metal intercalated transition metal di-chalcogenides potential candidates for several applications including electrochemical metallization cells and contacts in electronics based on 2D materials.
Highlights
In addition to these applications, the presence of a vdW gap between layers makes TMDCs attractive as potential hosts for intercalation with electron donor or acceptor species
From a basic science point of view, metal intercalation enabled the exploration of interesting material properties; for example, 3d transition metal species such as V, Cr, Mn, Fe, Co, and Ni intercalated into group V TMDCs form ordered superlattices that exhibit ferromagnetic and antiferromagnetic orderings depending on the concentration and temperature
We report on density functional theory (DFT) calculations to answer these questions with the objective of helping assess the possible use of intercalated TMDCs in applications of interest in nanoelectronics and energy storage
Summary
In addition to these applications, the presence of a vdW gap between layers makes TMDCs attractive as potential hosts for intercalation with electron donor or acceptor species. Intercalation of group VI TMDCs with alkali metals has been investigated for nanoelectronics, energy storage, and catalysis applications. The energetics of the intercalation process and the resulting atomic structures as a function of intercalate concentration are not known, nor are the ionic mobility and the evolution of the electronic structure during metallic loading. We report on density functional theory (DFT) calculations to answer these questions with the objective of helping assess the possible use of intercalated TMDCs in applications of interest in nanoelectronics and energy storage. The calculations in this paper demonstrate that electrochemical intercalation is possible up to very high metal concentrations with an accompanying reduction in electrical resistance.
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