Superconductivity in Single Crystals of Lu3T4Ge13–x (T = Co, Rh, Os) and Y3T4Ge13–x (T = Ir, Rh, Os)

K. Binod; Iain W. H. Oswald; Jiakui K. Wang; Gregory T. McCandless; Julia Y. Chan; E. Morosan

doi:10.1021/cm504658h

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Superconductivity in Single Crystals of Lu₃T₄Ge_13–x (T = Co, Rh, Os) and Y₃T₄Ge_13–x (T = Ir, Rh, Os)

K. Binod Iain W. H. Oswald Jiakui K. Wang Gregory T. McCandless Julia Y. Chan E. Morosan

Year: 2015 Journal: Chemistry of Materials Vol: 27 (7)Pages: 2488-2494 Publisher: American Chemical Society

DOI: 10.1021/cm504658h

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Abstract

Single crystals of Lu3T4Ge13–x (T = Co, Rh, Os) and Y3T4Ge13–x (T = Ir, Rh, Os) have been grown using the self-flux method and found to adopt the Yb3Rh4Sn13–x structure type. Magnetization and specific heat measurements confirm that all compounds are bulk superconductors, some with reduced superconducting gaps determined from specific heat suggesting multiband superconductivity. However, an unusual increase of the electrical resistivity and a decrease of the charge carrier density on cooling in the normal state are observed for all six compounds even though density functional periodic calculations reveal a metallic ground state. We empirically show that large atomic displacement parameter ratios in the R3T4Ge13–x compounds are correlated with the semiconductor-like behavior, which resolves the contradiction between the experiment and the calculations.

Keywords:

Superconductivity Electrical resistivity and conductivity Condensed matter physics Magnetization Materials science Ground state Metal Type-II superconductor Specific heat Semiconductor Crystallography Analytical Chemistry (journal) Chemistry Physics Atomic physics Magnetic field

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Rare-earth and actinide compounds

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Superconductivity in Single Crystals of Lu₃T₄Ge_13–x (T = Co, Rh, Os) and Y₃T₄Ge_13–x (T = Ir, Rh, Os)

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