Author
Listed:
- Hoon Kim
(Institute for Basic Science
Pohang University of Science and Technology)
- Jin-Kwang Kim
(Institute for Basic Science
Pohang University of Science and Technology)
- Junyoung Kwon
(Pohang University of Science and Technology)
- Jimin Kim
(Institute for Basic Science
Pohang University of Science and Technology)
- Hyun-Woo J. Kim
(Institute for Basic Science
Pohang University of Science and Technology)
- Seunghyeok Ha
(Institute for Basic Science
Pohang University of Science and Technology)
- Kwangrae Kim
(Institute for Basic Science
Pohang University of Science and Technology)
- Wonjun Lee
(Institute for Basic Science
Pohang University of Science and Technology)
- Jonghwan Kim
(Institute for Basic Science
Pohang University of Science and Technology)
- Gil Young Cho
(Institute for Basic Science
Pohang University of Science and Technology)
- Hyeokjun Heo
(Seoul National University)
- Joonho Jang
(Seoul National University)
- C. J. Sahle
(The European Synchrotron)
- A. Longo
(The European Synchrotron
UOS Palermo)
- J. Strempfer
(Argonne National Laboratory)
- G. Fabbris
(Argonne National Laboratory)
- Y. Choi
(Argonne National Laboratory)
- D. Haskel
(Argonne National Laboratory)
- Jungho Kim
(Argonne National Laboratory)
- J. -W. Kim
(Argonne National Laboratory)
- B. J. Kim
(Institute for Basic Science
Pohang University of Science and Technology)
Abstract
Spin nematic is a magnetic analogue of classical liquid crystals, a fourth state of matter exhibiting characteristics of both liquid and solid1,2. Particularly intriguing is a valence-bond spin nematic3–5, in which spins are quantum entangled to form a multipolar order without breaking time-reversal symmetry, but its unambiguous experimental realization remains elusive. Here we establish a spin nematic phase in the square-lattice iridate Sr2IrO4, which approximately realizes a pseudospin one-half Heisenberg antiferromagnet in the strong spin–orbit coupling limit6–9. Upon cooling, the transition into the spin nematic phase at TC ≈ 263 K is marked by a divergence in the static spin quadrupole susceptibility extracted from our Raman spectra and concomitant emergence of a collective mode associated with the spontaneous breaking of rotational symmetries. The quadrupolar order persists in the antiferromagnetic phase below TN ≈ 230 K and becomes directly observable through its interference with the antiferromagnetic order in resonant X-ray diffraction, which allows us to uniquely determine its spatial structure. Further, we find using resonant inelastic X-ray scattering a complete breakdown of coherent magnon excitations at short-wavelength scales, suggesting a many-body quantum entanglement in the antiferromagnetic state10,11. Taken together, our results reveal a quantum order underlying the Néel antiferromagnet that is widely believed to be intimately connected to the mechanism of high-temperature superconductivity12,13.
Suggested Citation
Hoon Kim & Jin-Kwang Kim & Junyoung Kwon & Jimin Kim & Hyun-Woo J. Kim & Seunghyeok Ha & Kwangrae Kim & Wonjun Lee & Jonghwan Kim & Gil Young Cho & Hyeokjun Heo & Joonho Jang & C. J. Sahle & A. Longo , 2024.
"Quantum spin nematic phase in a square-lattice iridate,"
Nature, Nature, vol. 625(7994), pages 264-269, January.
Handle:
RePEc:nat:nature:v:625:y:2024:i:7994:d:10.1038_s41586-023-06829-4
DOI: 10.1038/s41586-023-06829-4
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