Results in Physics (Jan 2023)

Pressure-induced phase transition and band-gap decrease in semiconducting Na3Bi(IO3)6

  • Robin Turnbull,
  • Javier González-Platas,
  • Akun Liang,
  • Dequan Jiang,
  • Yonggang Wang,
  • Catalin Popescu,
  • Plácida Rodríguez-Hernández,
  • Alfonso Muñoz,
  • Jordi Ibáñez,
  • Daniel Errandonea

Journal volume & issue
Vol. 44
p. 106156

Abstract

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We report a combined experimental/theoretical high-pressure study of Na3Bi(IO3)6 under compression to 11.2 GPa at ambient temperature. Through a combination of single-crystal and powder synchrotron X-ray diffraction, optical absorption measurements and ab initio density functional theory calculations we unambiguously show a first-order pressure-induced phase transition at around 9.5 GPa from the ambient pressure phase, referred to here as α-Na3Bi(IO3)6, to a new crystalline structure referred to here as β-Na3Bi(IO3)6. The triclinic (P-1) to triclinic (P1) phase transition is characterised by a doubling of the primitive cell volume, whereby the crystallographic b-axis doubles in length, and by a decrease in the volume per formula unit of approximately 3 %. The phase transition is also characterised by an indirect → indirect electronic bandgap decrease of approximately 0.1 eV as measured by absorption spectroscopy (3.44(1) → 3.32(1) eV) and calculated via density functional calculations (2.48 → 2.33 eV). We also report the pressure evolution of the crystal lattice parameters and isothermal compressibility tensor of the ambient pressure phase α-Na3Bi(IO3)6, which reveals highly anisotropic compressibility and a bulk modulus of 30.4(7) GPa.

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