Abstract
The valleytronic state found in group-VI transition-metal dichalcogenides such as MoS2 has attracted immense interest since its valley degree of freedom could be used as an information carrier. However, valleytronic applications require spontaneous valley polarization. Such an electronic state is predicted to be accessible in a new ferroic family of materials, i.e., ferrovalley materials, which features the coexistence of spontaneous spin and valley polarization. Although many atomic monolayer materials with hexagonal lattices have been predicted to be ferrovalley materials, no bulk ferrovalley material candidates have been reported or proposed. Here, we show that a new non-centrosymmetric van der Waals (vdW) semiconductor Cr0.32Ga0.68Te2.33, with intrinsic ferromagnetism, is a possible candidate for bulk ferrovalley material. This material exhibits several remarkable characteristics: (i) it forms a natural heterostructure between vdW gaps, a quasi-two-dimensional (2D) semiconducting Te layer with a honeycomb lattice stacked on the 2D ferromagnetic slab comprised of the (Cr, Ga)-Te layers, and (ii) the 2D Te honeycomb lattice yields a valley-like electronic structure near the Fermi level, which, in combination with inversion symmetry breaking, ferromagnetism, and strong spin-orbit coupling contributed by heavy Te element, creates a possible bulk spin-valley locked electronic state with valley polarization as suggested by our DFT calculations. Further, this material can also be easily exfoliated to 2D atomically thin layers. Therefore, this material offers a unique platform to explore the physics of valleytronic states with spontaneous spin and valley polarization in both bulk and 2D atomic crystals.
Original language | English |
---|---|
Pages (from-to) | 4683-4690 |
Number of pages | 8 |
Journal | Journal of the American Chemical Society |
Volume | 145 |
Issue number | 8 |
DOIs | |
State | Published - Mar 1 2023 |
Funding
This work was supported by the US Department of Energy under grants DE-SC0019068 and DE-SC0014208 (support for personnel, material discovery and synthesis, magnetic measurements, and data analyses). N.A. and L.M. acknowledge the support by NSF through the Pennsylvania State University Materials Research Science and Engineering Center (MRSEC) DMR-2011839 (2020- 2026). Y.C. and J.Z. acknowledge the support by the NSF-MIP 2DCC under award number DMR-2039351. J.H. and V.G. acknowledge the support by the NSF-MIP 2DCC under award number DMR-2210933. A portion of this research used resources at the Spallation Neutron Source, a DOE Office of Science User Facility operated by the Oak Ridge National Laboratory. The authors also acknowledge technical support of transport measurement by Wei Ning and technical assistance on the TOPAZ neutron experiments by Helen He. This work was supported by the US Department of Energy under grants DE-SC0019068 and DE-SC0014208 (support for personnel, material discovery and synthesis, magnetic measurements, and data analyses). N.A. and L.M. acknowledge the support by NSF through the Pennsylvania State University Materials Research Science and Engineering Center (MRSEC) DMR-2011839 (2020– 2026). Y.C. and J.Z. acknowledge the support by the NSF-MIP 2DCC under award number DMR-2039351. J.H. and V.G. acknowledge the support by the NSF-MIP 2DCC under award number DMR-2210933. A portion of this research used resources at the Spallation Neutron Source, a DOE Office of Science User Facility operated by the Oak Ridge National Laboratory. The authors also acknowledge technical support of transport measurement by Wei Ning and technical assistance on the TOPAZ neutron experiments by Helen He.
Funders | Funder number |
---|---|
NSF-MIP 2DCC | DMR-2039351, DMR-2210933 |
Pennsylvania State University Materials Research Science and Engineering Center | |
National Science Foundation | |
U.S. Department of Energy | DE-SC0014208, DE-SC0019068 |
Office of Science | |
Oak Ridge National Laboratory | |
Materials Research Science and Engineering Center, Harvard University | DMR-2011839 |