Inhomogeneous dynamic state in the double trillium lattice antiferromagnet KBaFe2(PO4)3
Abstract
The three-dimensional (3D) magnet KBaFe2(PO4)3 hosts a double-trillium lattice of Fe3+ (spin, S=5/2) ions offering a prototypical platform to study the frustration induced effects in 3D. Through magnetization, specific heat, 31P nuclear magnetic resonance (NMR), and muon spin relaxation (μSR) experiments, supported by first principles calculations, we uncover an unconventional ground state. Despite strong antiferromagnetic interactions with a large Curie-Weiss temperature θ CW = -70(2) K, no magnetic long-range order is observed down to 30 mK. Below T 3.5 K, the NMR linewidth becomes nearly field-independent and the spin-spin relaxation rate 1/T2 saturates, accompanied by an inhomogeneous distribution of transverse nuclear magnetization Mxy. The latter indicates the emergence of short-range dynamical correlations, which was further corroborated by a robust and field-insensitive broad maximum in specific heat. In μSR, we detect neither a static internal field nor spin freezing; instead the relaxation remains dynamic and is best described by two coexisting dynamic relaxation channels: a dominant fast (sporadic) channel and a slower Markovian component. Their differing weights and fluctuation rates suggest microscopic inhomogeneity in spin dynamics. Altogether, KBaFe2(PO4)3 exemplifies a rare high-spin stochiometric 3D antiferromagnet that evades ordering and instead fosters a mosaic of spin dynamics driven by strong geometric frustration intrinsic to the trillium lattice.
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