Effect of uniaxial stress on the magnetic phases of CeAuSb2

Abstract

We present results of measurements of resistivity of under the combination of c-axis magnetic field and in-plane uniaxial stress. In unstressed there are two magnetic phases. The low-field A phase is a single-component spin-density wave (SDW), with q = (η, η, 1/2), and the high-field B phase consists of microscopically coexisting (η, η, 1/2) and (η, -η, 1/2) spin-density waves. Pressure along a 100 lattice direction is a transverse field to both of these phases, and so initially has little effect, however eventually induces new low- and high-field phases in which the principal axes of the SDW components appear to have rotated to the 100 directions. Under this strong 100 compression, the field evolution of the resistivity is much smoother than at zero strain: In zero strain, there is a strong first-order transition, while under strong 100 it becomes much broader. We hypothesize that this is a consequence of the uniaxial stress lifting the degeneracy between the (100) and (010) directions.