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Area of Science:

  • Condensed Matter Physics
  • Materials Science
  • Quantum Magnetism

Background:

  • The search for quantum spin liquids (QSL) is crucial for understanding emergent quantum phenomena.
  • Investigating novel materials for QSL properties can lead to breakthroughs in superconductivity.

Purpose of the Study:

  • To report the discovery of a potential QSL candidate material, β-NaYbO₂.
  • To characterize the structural and magnetic properties of β-NaYbO₂.

Main Methods:

  • Single crystal growth of α- and β-NaYbO₂.
  • Synchrotron X-ray single-crystal diffraction and powder diffraction.
  • Neutron powder diffraction and pair distribution function analysis.
  • Magnetic susceptibility measurements down to 0.4 K.

Main Results:

  • Successfully grew novel α- and β-NaYbO₂ single crystals.
  • Unambiguously determined the 3D pyrochlore structure of β-NaYbO₂ (space group *R*3̅*m*).
  • Observed no long-range magnetic order or spin glass behavior down to 0.4 K, with a low spin frustration factor of 17.5.
  • Identified that the potential QSL state is broken under high magnetic fields, leading to spin ordering.

Conclusions:

  • β-NaYbO₂ is a promising candidate for a quantum spin liquid.
  • This material provides a new platform for studying novel quantum states and their properties.
  • Further research on NaYbO₂ could illuminate mechanisms for high-temperature superconductivity.