Nature Communications (Mar 2024)

Pressure-tuned quantum criticality in the large-D antiferromagnet DTN

  • Kirill Yu. Povarov,
  • David E. Graf,
  • Andreas Hauspurg,
  • Sergei Zherlitsyn,
  • Joachim Wosnitza,
  • Takahiro Sakurai,
  • Hitoshi Ohta,
  • Shojiro Kimura,
  • Hiroyuki Nojiri,
  • V. Ovidiu Garlea,
  • Andrey Zheludev,
  • Armando Paduan-Filho,
  • Michael Nicklas,
  • Sergei A. Zvyagin

DOI
https://doi.org/10.1038/s41467-024-46527-x
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 8

Abstract

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Abstract Strongly correlated spin systems can be driven to quantum critical points via various routes. In particular, gapped quantum antiferromagnets can undergo phase transitions into a magnetically ordered state with applied pressure or magnetic field, acting as tuning parameters. These transitions are characterized by z = 1 or z = 2 dynamical critical exponents, determined by the linear and quadratic low-energy dispersion of spin excitations, respectively. Employing high-frequency susceptibility and ultrasound techniques, we demonstrate that the tetragonal easy-plane quantum antiferromagnet NiCl2 ⋅ 4SC(NH2)2 (aka DTN) undergoes a spin-gap closure transition at about 4.2 kbar, resulting in a pressure-induced magnetic ordering. The studies are complemented by high-pressure-electron spin-resonance measurements confirming the proposed scenario. Powder neutron diffraction measurements revealed that no lattice distortion occurs at this pressure and the high spin symmetry is preserved, establishing DTN as a perfect platform to investigate z = 1 quantum critical phenomena. The experimental observations are supported by DMRG calculations, allowing us to quantitatively describe the pressure-driven evolution of critical fields and spin-Hamiltonian parameters in DTN.