Magnetic field tuned superconducting and normal phase magnetism in CeCo0.5Rh0.5In5
Abstract
By tuning superconductivity with an applied magnetic field, we use neutrons to compare the magnetic ordered phases in superconducting and normal states of CeCo0.5Rh0.5In5. At zero field, CeCo0.5Rh0.5In5 displays both superconductivity (Tc=1.3 K) and spatially long-ranged commensurate antiferromagnetism (TN=2.5 K, Q0=(1 2, 1 2, 1 2)). Neutron spectroscopy fails to measure propagating magnetic excitations with only temporally overdamped fluctuations observable. On applying a magnetic field we find anisotropic behavior in the static magnetism. When the field is along the crystallographic c-axis, no change in the static magnetic response is observable. However when the field is oriented within the a-b plane, an increase in TN and change in the critical response are measured. At low temperatures in the superconducting phase, the elastic magnetic intensity increases linearly ( |H|) with small a-b oriented fields. However, this trend is interrupted at intermediate fields where commensurate block magnetism with propagation vector Q=(1 2, 1 2, 1 4) forms. For large applied fields in the [1 1 0] direction which completely suppresses superconductivity, weakly incommensurate magnetic order along L is observed to replace the commensurate response present in the superconducting and vortex phases. We suggest field-induced incommensurate static magnetism, present in the normal state of superconducting and antiferromagnetic CeCo0.5Rh0.5In5 for a-b plane oriented magnetic fields. We speculate that these field dependent properties are tied to the field induced anisotropy associated with the local Ce3+ crystal field environment of the tetragonal `115' structure.
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