Prevailing orbital excitations in paramagnetic kagome superconductor Cs(V0.95Ti0.05)3Sb5
Abstract
Using the muon as a sensitive local magnetic probe, we investigated the layered kagome superconductor Cs(V0.95Ti0.05)3Sb5, a material notably devoid of both static magnetic moments and long-range charge order. Our transverse-field μSR measurements reveal that the local magnetic susceptibility, obtained via the muon Knight shift, is dominated by orbital excitations with a split energy levels around 20 meV. Meanwhile, the persistence of itinerant electron paramagnetism down to 5 K and 7 T confirms the absence of static magnetism within this regime. In addition, zero-field (ZF) μSR experiments detect a significant increase in the inhomogeneous nuclear dipolar field distribution below a featured temperature at 70 K. We attribute this ZF-μSR feature to the emergence of local lattice distortions at low temperatures, potentially arising from orbital ordering. Significantly, our study establishes that orbital excitations constitute an intrinsic property of the layered V-Sb kagome lattice. Despite its small magnitude, spin-orbit coupling plays a crucial role in governing the lattice dynamics, potentially driving the emergence of novel phenomena such as phonon carrying angular momentum in crystals with non-chiral point groups.
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