Pressure-tuned quantum criticality in the large-\(D\) antiferromagnet DTN
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 cha...
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| creator | Kirill Yu Povarov Graf, David E Hauspurg, Andreas Zherlitsyn, Sergei Wosnitza, Joachim Sakurai, Takahiro Ohta, Hitoshi Kimura, Shojiro Nojiri, Hiroyuki Garlea, V Ovidiu Zheludev, Andrey Paduan-Filho, Armando Nicklas, Michael Zvyagin, Sergei A |
| description | 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 NiCl\(_{2}\cdot\)4SC(NH\(_2\))\(_2\) (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. |
| doi_str_mv | 10.48550/arxiv.2306.15450 |
| format | Article |
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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 NiCl\(_{2}\cdot\)4SC(NH\(_2\))\(_2\) (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.</description><identifier>EISSN: 2331-8422</identifier><identifier>DOI: 10.48550/arxiv.2306.15450</identifier><language>eng</language><publisher>Ithaca: Cornell University Library, arXiv.org</publisher><subject>Anisotropy ; Antiferromagnetism ; Critical phenomena ; Critical point ; Electron paramagnetic resonance ; Electron spin ; Excitation spectra ; Hamiltonian functions ; Neutron diffraction ; Neutrons ; Phase transitions ; Spin resonance</subject><ispartof>arXiv.org, 2024-03</ispartof><rights>2024. 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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. 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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.</abstract><cop>Ithaca</cop><pub>Cornell University Library, arXiv.org</pub><doi>10.48550/arxiv.2306.15450</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Anisotropy Antiferromagnetism Critical phenomena Critical point Electron paramagnetic resonance Electron spin Excitation spectra Hamiltonian functions Neutron diffraction Neutrons Phase transitions Spin resonance |
| title | Pressure-tuned quantum criticality in the large-\(D\) antiferromagnet DTN |
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