In-Plane Ferromagnetism and Critical Dynamics in Alkali-Deficient K1-xCrTe2 (with x ≈ 0.3) Single Crystals

Abstract

Layered chromium tellurides are model systems for studying low-dimensional magnetism in van der Waals materials. We report the synthesis and characterization of K1-xCrTe2 single crystals (x ≈ 0.3), which crystallize in the Cm space group with trigonal prismatic K+ coordination, unlike the octahedral environments of more stoichiometric ACrX2 compounds. Magnetization measurements show a sharp ferromagnetic transition at T C=117 K and in-plane magnetic anisotropy, supported by density functional theory. Neutron diffraction reveals ferromagnetic alignment of Cr spins within and between layers. This contrasts with the out-of-plane A-type antiferromagnetism in LiCrTe2 and NaCrTe2, but resembles CrTe2. These differences likely arise from changes in interlayer spacing, Cr oxidation state, or stacking. AC susceptibility and μSR indicate short-range order above T C and dynamic behavior below. Overall, K1-xCrTe2 provides a tunable platform for studying spin orientation and dimensionality in two-dimensional magnets.