Above-room-temperature intrinsic ferromagnetism in ultrathin van der Waals crystal Fe$_{3+x}$GaTe$_2$

TL;DR

This study demonstrates tunable above-room-temperature intrinsic ferromagnetism in ultrathin van der Waals Fe$_{3+x}$GaTe$_2$ crystals, with enhanced Curie temperature and magnetic properties, promising for 2D spintronics applications.

Contribution

It reports the first observation of tunable above-room-temperature intrinsic ferromagnetism in ultrathin vdW Fe$_{3+x}$GaTe$_2$, with detailed experimental and theoretical analysis.

Findings

Curie temperature increased to 376 K with Fe content

Record-high TC of 340 K in 3-nm ultrathin crystal

Large room-temperature perpendicular magnetic anisotropy

Abstract

Two-dimensional (2D) van der Waals (vdW) magnets are crucial for ultra-compact spintronics. However, so far, no vdW crystal has exhibited tunable above-room-temperature intrinsic ferromagnetism in the 2D ultrathin regime. Here, we report the tunable above-room-temperature intrinsic ferromagnetism in ultrathin vdW crystal Fe$_{3+x}$GaTe$_2$ ($x$ = 0 and 0.3). By increasing the Fe content, the Curie temperature (TC) and room-temperature saturation magnetization of bulk Fe$_{3+x}$GaTe$_2$ crystals are enhanced from 354 to 376 K and 43.9 to 50.4 emu/g, respectively. Remarkably, the robust anomalous Hall effect in 3-nm Fe$_{3.3}$GaTe$_2$ indicate a record-high TC of 340 K and a large room-temperature perpendicular magnetic anisotropy energy of 6.6 * 10^5 J/m$^3$, superior to other ultrathin vdW ferromagnets. First-principles calculations reveal the asymmetric density of states and an additional large spin exchange interaction in ultrathin Fe$_{3+x}$GaTe$_2$ responsible for robust intrinsic ferromagnetism and higher Tc. This work opens a window for above-room-temperature ultrathin 2D magnets in vdW-integrated spintronics.