| Popis: |
The magnetic ground state of iron selenide (FeSe) has been a topic of debate, with experimental evidence suggesting stripe spin fluctuations as predominant at low temperatures, while density functional theory (DFT) calculations using the Generalized Gradient Approximation (GGA) have historically predicted the antiferromagnetic (AFM) dimer configuration. In this study, we utilize the $\text{r}^{2}\text{SCAN}$ functional, a variant of the Strongly Constrained and Appropriately Normed ($\text{SCAN}$) meta-GGA, to investigate the magnetic configurations of FeSe. Our findings indicate that $\text{r}^{2}\text{SCAN}$ predicts a stripe-AFM ground state with an anti-parallel spin alignment between layers. The energy difference between the parallel and anti-parallel inter-planar spin alignments is approximately 1.7 meV/atom, predicting a significant but previously unreported interlayer spin coupling not yet observed by experiments. This study underscores the importance of accurate exchange-correlation functionals, such as $\text{r}^{2}\text{SCAN}$, in predicting the magnetic ground state in complex materials like FeSe, highlighting its potential to predict magnetic interactions more reliably than traditional GGA functionals by adhering to exact constraints. |
