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Probing and tuning geometric frustration in an organic quantum magnet via elastocaloric measurements under strain

Francisco Lieberich, Yohei Saito, Yassine Agarmani, T. Sasaki, N. Yoneyama, Stephen M. Winter, Michael Lang, Elena Gati

2025Science Advances6 citationsDOIOpen Access PDF

Abstract

Geometric frustration is a key ingredient in the emergence of exotic states of matter, such as the quantum spin liquid in Mott insulators. Although there has been intense interest in experimentally tuning frustration in candidate materials, achieving precise and continuous control has remained a major hurdle-particularly in accessing the properties of the ideally frustrated lattice. Here, we show that large, finely controlled anisotropic strains can effectively tune the degree of geometric frustration in the Mott insulating [Formula: see text]-a slightly anisotropic triangular-lattice quantum magnet. Using thermodynamic measurements of the elastocaloric effect, we experimentally map out a temperature-strain phase diagram that captures both the ground state of the isotropic lattice and the less frustrated parent state. Our results provide a benchmark for calculations of the triangular-lattice Hubbard model as a function of frustration and highlight the power of lattice engineering as a route to realizing perfectly frustrated quantum materials.

Topics & Concepts

FrustrationMagnetStrain (injury)QuantumCondensed matter physicsMaterials scienceMolecular magnetsPhysicsQuantum mechanicsMagnetic fieldBiologyMagnetizationAnatomyOrganic and Molecular Conductors ResearchAdvanced Condensed Matter PhysicsThermal Expansion and Ionic Conductivity
Probing and tuning geometric frustration in an organic quantum magnet via elastocaloric measurements under strain | Litcius