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High-Pressure X-Ray Diffraction Study of Scheelite-type Perrhenates

Materials Science 2026-02-26 v1 Chemical Physics

Abstract

The effects of pressure on the crystal structure of scheelite-type perrhenates were studied using synchrotron powder X-ray diffraction and density-functional theory. At ambient conditions, the studied materials AgReO4, KReO4, and RbReO4, exhibit a tetragonal scheelite-type crystal structure described by space group I41/a. Under compression, a transition from scheelite-to-M{\prime}-fergusonite (space group P21/c) was observed at 1.6 and 7.4 GPa for RbReO4 and KReO4, respectively. The transition involves a relative volume decrease. On the other hand, AgReO4 underwent a phase transition to the M-fergusonite structure (space group I2/a) at 13.6 GPa. In this case there is no appreciable volume discontinuity. The room-temperature pressure-volume equation of state for the three studied perrhenates was estimated using a second-order Birch-Murnaghan equation of state. The results for the low-pressure phase are confirmed by density-functional theory calculations. The analysis of the bulk modulus shows that the compressibility of the compounds decreases following the sequence RbReO4 > KReO4 > AgReO4, which is related to the compressibility of the RbO8, KO8, and AgO8 bidisphenoid units. Density-functional theory also offers valuable insights into the elastic constants. Despite giving a good description for the low-pressure phase in the three compounds, density-functional theory cannot catch the structural phase transition observed in experiments. Reasons for it are discussed in the manuscript.

Keywords

Cite

@article{arxiv.2602.22156,
  title  = {High-Pressure X-Ray Diffraction Study of Scheelite-type Perrhenates},
  author = {Neha Bura and Pablo Botella and Catalin Popescu and Frederico Alabarse and Ganapathy Vaitheeswaran and Alfonso Munoz and Brendan J. Kennedy and Jose Luis Rodrigo Ramon and Josu Sanchez-Martin and Daniel Errandonea},
  journal= {arXiv preprint arXiv:2602.22156},
  year   = {2026}
}

Comments

32 pages, 9 figures, 6 tables, 44 references

R2 v1 2026-07-01T10:52:29.158Z