The
surface termination of MXenes greatly determines the electrochemical
properties and ion kinetics on their surfaces. So far, hydroxyl-,
oxygen-, and fluorine-terminated MXenes have been widely studied for
energy storage applications. Recently, sulfur-functionalized MXene
structures, which possess low diffusion barriers, have been proposed
as candidate materials to enhance battery performance. We performed
first-principles calculations on the structural, stability, electrochemical,
and ion dynamic properties of Li-adsorbed sulfur-functionalized groups
3B, 4B, 5B, and 6B transition-metal (M)-based MXenes (i.e., M2CS2 with M = Sc, Ti, Zr, Hf, V, Nb, Ta, Cr, Mo,
and W). We performed phonon calculations, which indicated that all
of the above M2CS2 MXenes, except for Sc, are
dynamically stable at T = 0 K. The ground-state structure
of each M2CS2 monolayer depends on the type
of M atom. For instance, while sulfur prefers to sit at the FCC site
on Ti2CS2, it occupies the HCP site of Cr-based
MXene. We determined the Li adsorption configurations at different
concentrations using the cluster expansion method. The highest maximum
open-circuit voltages were computed for the group 4B element (i.e.,
Ti, Zr, and Hf)-based M2CS2, which are larger
than 2.1 V, while their average voltages are approximately 1 V. The
maximum voltage for the group 6B element (i.e., Cr, Mo, W)-based M2CS2 is less than 1 V, and the average voltage is
less than 0.71 V. We found that S functionalization is helpful for
capacity improvements over the O-terminated MXenes. In this respect,
the computed storage gravimetric capacity may reach up to 417.4 mAh/g
for Ti2CS2 and 404.5 mAh/g for V2CS2. Ta-, Cr-, Mo-, and W-based M2CS2 MXenes show very low capacities, which are less than 100 mAh/g.
The Li surface diffusion energy barriers for all of the considered
MXenes are less than 0.22 eV, which is favorable for high charging
and discharging rates. Finally, ab initio molecular dynamic simulations
performed at 400 K and bond-length analysis with respect to Li concentration
verify that selected promising systems are robust against thermally
induced perturbations that may induce structural transformations or
distortions and undesirable Li release.
