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Evidence for spin liquid behavior in the frustrated three-dimensional $S = 1/2$ Heisenberg garnet NaCa$_{2}$Cu$_{2}$(VO$_{4}$)$_{3}$

Three-dimensional quantum spin liquids have remained elusive, hindered by reduced quantum fluctuations from larger lattice connectivity inherent to high-dimensional systems. Here, we investigate the remarkable persistence of dynamical short-range magnetic correlations in the nearly body-centered cubic garnet NaCa$_{2}$Cu$_{2}$(VO$_{4}$)$_{3}$ down to $T = 50$ mK, two orders of magnitude below its Curie-Weiss temperature. Using a combination of neutron and muon spectroscopies plus numerical simulations, we demonstrate that a dynamical regime emerges, characterized by a dual response in the inelastic spectrum composed of short-live dispersive excitations and a quasi-elastic component. Strongly frustrated exchange interactions combined with subtle temperature-dependent Jahn-Teller spin-lattice effects are a plausible mechanism to explain the origin of this spin-liquid behavior.

preprint2025arXivOpen access
Y. AlexanianR. KumarH. ZeroualB. BernuL. Mangin-ThroJ. R. StewartJ. M. WilkinsonS. BhattacharyaP. L. PauloseF. BertP. MendelsB. FåkE. Kermarrec
cond-mat.str-elcond-mat.mtrl-sci
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Y. AlexanianR. KumarH. ZeroualB. BernuL. Mangin-ThroJ. R. StewartJ. M. WilkinsonS. BhattacharyaP. L. PauloseF. BertP. MendelsB. FåkE. Kermarrec

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