First Principles Studies of Fe-intercalated $\mathrm{NbS_2}$

Layered transition metal dichalcogenides (TMDs) can allow for the intercalation of magnetic ions, resulting in novel magnetic and electronic properties which can be tuned by altering intercalant species and concentration. Recent experiments on $\mathrm{Fe_{1/3}NbS_2}$, a bulk antiferromagnet with a N\'{e}el temperature of 42K, have shown that an applied current can reversibly switch the magnetic order, which is read out in the resistivity*. It is hypothesized that the magnetoelectric response to the current is due to a redistribution of magnetic domains**. To shed light on these findings, we examine the ground state structure and magnetic properties of $\mathrm{Fe_{1/3}NbS_2}$ using density functional theory calculations. We compute energetics of different experimentally proposed magnetic orderings, and the corresponding band structures and Fermi surfaces. Implications of our calculations for the reported switching behavior and resistivity response are discussed.\newline
* Nair et al., arXiv:1907.11698 (2019)\newline
**Little et al., arXiv:1908.00657 (2019)