Highly fluctuating double-q magnetic order in the van der Waals metal CeTe3

Abstract

CeTe3 is a van der Waals antiferromagnet composed of magnetic [CeTe]+ layers coupled to highly conducting Te0.5- square nets. Its simple quasi-two-dimensional electronic structure and cleavable nature make it an appealing platform for exploring correlated magnetism in reduced dimensions. To clarify the nature of its low-temperature state, we performed single-crystal neutron diffraction down to 0.3 K, complemented by scanning tunneling microscopy. A magnetic transition near 1.5 K gives rise to incommensurate Bragg peaks at q(0.17,0,0.31), consistent with a double-q magnetic order whose moments are predominantly aligned along the c axis. The strongly reduced ordered moment is consistent with enhanced quantum fluctuations driven by c-f hybridization, while the deviation of the propagation vectors from simple nesting suggests a coupling to residual charge-density-wave instabilities of the quasi-one-dimensional Te-derived bands. These results indicate that CeTe3 hosts a correlated magnetic ground state where spin and itinerant charge degrees of freedom are intimately linked in the van der Waals limit.