An ab initio study of magnetic structure transitions of FePS3 under high pressure
Abstract
Recent experimental work shows that FePS3 undergoes phase transitions from C2/m (β107) to C2/m (β90) at 6 GPa and then to metallic P31m at 14 GPa, with the magnetic ordering wave vector turning from k=(0112) to k=(010) at 2 GPa and to short-range magnetic order accompanying the insulator-metal transition. By preserving the magnetic point groups in ab \ initio calculations we report the following: (1) We successfully reproduce the first magnetic structure transition at 1.2 GPa and briefly discuss the influence of the Hubbard U parameter on this transition. This isostructural transition causes a change of the Brillouin zone from base-centered monoclinic to primitive monoclinic, and an indrect band gap to direct band gap transition. (2) There is a rotation of the Fe-S octahedron about 0.5 through the [001] axis before the neighboring layers shift. (3) The shift between neighboring layers is predicted to occur at 10.0 GPa and reverses the energy order between dx2-y2 and dxy. (4) A sudden decrease of Fe-S bond length to 2.20 \ accompanies the vanishing of magnetic moment in the insulator-metal transition. Our work shows the importance of symmetries of magnetic structures in pressure-induced phase transition of magnetic systems.
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