Structural transition and uranium valence change in UTe\(_2\) at high pressure revealed by x-ray diffraction and spectroscopy

High pressure x-ray diffraction up to 30 GPa and resonant emission x-ray spectroscopy and partial fluorescence yield x-ray absorption spectroscopy up to 52 GPa were used to study how the structural and electronic properties of UTe\(_2\) evolve with pressure at room temperature. An orthorhombic to te...

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Bibliographic Details
Published in:arXiv.org 2024-03
Main Authors: Deng, Yuhang, Lee-Wong, Eric, Moir, Camilla M, Kumar, Ravhi S, Swedan, Nathan, Park, Changyong, Dmitry Yu Popov, Xiao, Yuming, Chow, Paul, Baumbach, Ryan E, Hemley, Russell J, Maple, M Brian
Format: Article
Language:English
Subjects:
Absorption spectroscopy
Bonding strength
Electronic properties
Emission spectra
High pressure
Phase diagrams
Phase transitions
Room temperature
Spectrum analysis
Superconductivity
Unconventional superconductivity
X ray absorption
X-ray diffraction
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Summary:High pressure x-ray diffraction up to 30 GPa and resonant emission x-ray spectroscopy and partial fluorescence yield x-ray absorption spectroscopy up to 52 GPa were used to study how the structural and electronic properties of UTe\(_2\) evolve with pressure at room temperature. An orthorhombic to tetragonal phase transition was observed to occur between 5 and 7 GPa, with a large volume collapse of nearly 11% and a nearest U-U distance increase by about 4%. This lower to higher symmetry transition suggests less 5f electron participation in bonding when the weakly correlated superconducting phase in the tetragonal structure of UTe\(_2\) appears. Beyond 7 GPa, no new structural transitions were found up to 30 GPa. The resonant x-ray emission spectra clearly demonstrate an intermediate valence of U, nearly +3.74 at 1.8 GPa and room temperature, and reveal that the U valence shifts towards 4+, passes through a peak at 2.8 GPa, and then decreases towards 3+ and settles down to a nearly constant value above 15 GPa. These experiments reveal that some fundamental structural and valence changes occur in UTe2 at relatively low pressures, which could be responsible for the interplay between unconventional superconductivity, magnetic ordering, and weakly correlated superconductivity that is manifested in the temperature-pressure phase diagram of UTe2.
ISSN:2331-8422