Hydrostatic and chemical pressure driven crossover from commensurate to the incommensurate state of the Weyl semimetal Mn3+xSn1-x

Abstract

The observation of large intrinsic anomalous Hall conductivity (AHC) in the non-collinear antiferromagnetic (AFM) phase of the Weyl semimetal Mn3Sn generates enormous interest in uncovering the entanglement between the real space magnetic ordering and the momentum space band structure. Previous studies show that changes in the magnetic structure induced by the application of hydrostatic and chemical pressure can significantly affect the AHC of Mn3+xSn1-x system. Here, we employ the muon spin relaxation/rotation (μ+SR) technique to systematically investigate the evolution of different magnetic states in the Mn3+xSn1-x as a function of hydrostatic and chemical pressure. We find two muon sites experimentally, which is also supported by our ab initio calculations. Our μ+SR experiments affirm that the x = 0.05 compound exhibits a commensurate magnetic state throughout the magnetically ordered phase below the Neel temperature TN ≈ 420~K in ambient pressure. In contrast, we observe an incommensurate magnetic state below TIC 175~K when a hydrostatic pressure of 1.5~GPa is applied. A similar transition from the commensurate to incommensurate state is also found with chemical pressure for x = 0.04 and x = 0.03, using μ+SR and elastic neutron scattering experiments. Using band structure calculations, we have shown the emergence of Fermi nesting in Mn3Sn and the subsequent development of incommensurate magnetic ordering under hydrostatic/chemical pressure.