Searching for efficient
electrode materials with high power density,
fast charge/discharge rate, and high conductivity is one of the key
challenges in the development of metal ion batteries. Herein, by means
of first-principles computations, we demonstrated that the two-dimensional
Nb2S2C monolayer is a promising anode material
for metal ion batteries. The Nb2S2C monolayer
has rather good kinetic and thermodynamic stability, and it is metallic
with considerable electronic states at the Fermi level. The production
of the Nb2S2C monolayer from its experimentally
known bulk phase via exfoliation strategies should be rather feasible
because of the small cleavage energy of 0.38 J/m2. All
the studied metal atoms, including Li, Na, K, and Mg, can be effectively
adsorbed on the surface of the Nb2S2C monolayer
with pronounced charge transfer. Especially, the diffusion of Li,
Na, and K atoms on the Nb2S2C monolayer is rather
feasible with a diffusion barrier of 0.23, 0.11, and 0.07 eV, respectively,
whereas Mg has a relatively high diffusion barrier of 0.47 eV. Remarkably,
the efficient accommodation of metal atoms on both sides of the Nb2CS2 monolayer results in a high theoretical capacity
of 194.36, 348.20, 157.60, and 690.52 mA h/g and an open circuit voltage
of 0.92, 0.31, 0.26, and 0.18 V for Li, Na, K, and Mg storage, respectively.
These results suggest that the Nb2S2C monolayer
can be utilized as a promising anode material for metal ion batteries
with high power density and good rate capacity.
