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Signatures of spin-liquid state in a 3D frustrated lattice compound KSrFe2(PO4)3 with <i>S</i> = 5/2

K. Boya, K. Nam, Kuldeep Kargeti, A. Jain, Rakesh Kumar, S. K. Panda, S. M. Yusuf, P. L. Paulose, U. K. Voma, E. Kermarrec, Kee Hoon Kim, B. Koteswararao

2022APL Materials22 citationsDOIOpen Access PDF

Abstract

A quantum spin-liquid is a spin disordered state of matter in which spins are strongly correlated and highly entangled with low-energy excitations. It has been often found in two-dimensional S = ½, highly frustrated spin networks but rarely observed in three-dimensional (3D) frustrated quantum magnets. Here, KSrFe2(PO4)3, forming a complicated 3D frustrated lattice with a spin moment S = 5/2, is investigated by thermodynamic, neutron diffraction measurements and electronic structure calculations. Despite the relatively sizable Curie–Weiss temperature θCW = −70 K, a conventional magnetic long-range order is confirmed to be absent down to 0.19 K. The magnetic heat capacity data follow the power-law behavior at the lowest temperature region, supporting gapless excitations in a 3D spin-liquid state. Strong geometrical spin frustration responsible for the spin-liquid feature is understood as originating from the almost comparable five competing nearest-neighbor antiferromagnetic exchange interactions, which form the complicated 3D frustrated spin network. All these results suggest that the compound KSrFe2(PO4)3, representing a unique 3D spin frustrated network, could be a rare example of forming a gapless spin-liquid state even with a large spin moment of S = 5/2.

Topics & Concepts

Quantum spin liquidCondensed matter physicsFrustrationAntiferromagnetismSpin (aerodynamics)Spin iceSpinsNeutron diffractionPhysicsGeometrical frustrationSpin polarizationMaterials scienceQuantum mechanicsElectronDiffractionThermodynamicsMagnetic monopoleAdvanced Condensed Matter PhysicsPhysics of Superconductivity and MagnetismMagnetic and transport properties of perovskites and related materials