Journal
PHYSICAL REVIEW B
Volume 104, Issue 6, Pages -Publisher
AMER PHYSICAL SOC
DOI: 10.1103/PhysRevB.104.064505
Keywords
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Funding
- U.S. Department of Energy Basic Energy Sciences [DE-SC-0020385]
- U.S. National Science Foundation [DMR-1453752, DMR-1933622]
- Center for Bright Beams, U.S. National Science Foundation [PHY-1549132]
- DOE-National Nuclear Security Administration (NNSA) Office of Experimental Sciences
- DOE-NNSA [DE-NA0003975]
- COMPRES under NSF [EAR-1606856]
- GSECARS through NSF [EAR-1634415]
- DOE [DE-FG02-94ER14466]
- DOE Office of Science [DE-AC02-06CH11357]
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The study investigated the electrical resistivity and crystal structure changes of Be22Re compound under high pressure, revealing a gradual decrease in critical temperature T-c. Through density functional theory calculations and X-ray diffraction experiments, the influence of lattice stiffening on the decrease in T-c was elucidated.
With T-c similar to 9.6K, Be22Re exhibits one of the highest critical temperatures among Be-rich compounds. We have carried out a series of high-pressure electrical resistivity measurements on this compound to 30 GPa. The data show that the critical temperature T-c is suppressed gradually at a rate of dT(c)/dP = -0.05K/GPa. Using density functional theory (DFT) calculations of the electronic and phonon density of states (DOS) and the measured critical temperature, we estimate that the rapid increase in lattice stiffening in Be22Re overwhelms a moderate increase in the electron-ion interaction with pressure, resulting in the decrease in T-c. High-pressure x-ray diffraction measurements show that the ambient pressure crystal structure of Be22Re persists to at least 154 GPa.
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