Magnesium-ion batteries have the potential to replace commercially available Li-ion batteries in the future due to their lower cost and sustainability. On the other hand, magnesium ions are dendrite-free and offer greater energy density and volumetric capacity due to their divalent nature. Conventional electrode materials face challenges in capturing magnesium ions. We assessed the feasibility of using Co-anti MXene (CoB/CoP) monolayers as electrode materials for Mg-ion batteries using density functional theory. The adsorption energy of CoB for Mg atoms is -2.88 eV in a vacuum (-4.46 and -4.55 eV for diglyme and triglyme effects calculated using the Vaspsol method), respectively. As predicted by molecular dynamics, MgCoB shows high stability at 300 K in the magnesium process. A diffusion coefficient of 3.57 × 10 cm s was determined at an ambient temperature of 300 K. The electrical conductivity per relaxation time (MgCoB) at 300 K is found to be 1.64 × 10 Ω m s with a corresponding chemical potential of -6.94 eV, respectively. The Co-anti MXenes have the potential to be used as anode materials in Mg-ion batteries.
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http://dx.doi.org/10.1039/d4cp03358b | DOI Listing |
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