Physical properties and electronic structure of La3Co and La3Ni intermetallic superconductors

Strychalska, Judyta; Roman, Marta; Sobczak, Zuzanna; Wiendlocha, Bartłomiej; Winiarski, Michał J.; Ronning, F.; Klimczuk, Tomasz

doi:10.1016/j.physc.2016.07.017

Cited by 7 publications

(2 citation statements)

References 35 publications

(54 reference statements)

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“…To try to quantify this effect, we may follow the route proposed for many d-band superconductors, like Vanadium and its alloys [34][35][36][37][38], Mo 3 Sb 7 [39], La 3 Co [40] or Y 3 Rh [41]. Assuming that the electronic correlations take mostly the form of spin fluctuations (electron-paramagnon interactions), characterized by the coupling constant λ sf , one can compute the superconducting critical temperature from the modified McMillan's formula [39,42]:…”

Section: Electronic Band Structurementioning

confidence: 99%

Iridium5d-electron driven superconductivity inThIr3

et al. 2019

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Polycrystalline sample of superconducting ThIr 3 was obtained by arc-melting Th and Ir metals. Powder x-ray diffraction revealed that the compound crystalizes in a rhombohedral crystal structure (R-3m, s.g. #166) with the lattice parameters: a = 5.3414(2) Å and c = 26.432(1) Å. Normal and superconducting states were studied by magnetic susceptibility, electrical resistivity and heat capacity measurements. The results showed that ThIr 3 is a type II superconductor (Ginzburg-Landau parameter κ = 33) with the critical temperature T c = 4.41 K. The heat capacity data yielded the Sommerfeld coefficient γ = 17.6 mJ mol -1 K -2 and the Debye temperature Θ D = 169 K. The ratio ΔC/(γT c ) = 1.6, where ΔC stands for the specific heat jump at T c , and the electron-phonon coupling constant λ e-p = 0.74 suggest that ThIr 3 is a moderate-strength superconductor. The experimental studies were supplemented by band structure calculations, which indicated that the superconductivity in ThIr 3 is governed mainly by 5d states of iridium. The significantly smaller band-structure value of Sommerfeld coefficient as well as the experimentally observed quadratic temperature dependence of resistivity and enhanced magnetic susceptibility suggest presence of electronic interactions in the system, which compete with superconductivity.

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Section: Electronic Band Structurementioning

confidence: 99%

Iridium5d-electron driven superconductivity inThIr3

et al. 2019

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“…In 2014 Ram and Kanchana [5] compared Superconducting properties like transition temperature and Fermi surface topology of La 3 In to La 3 InO & La 3 InN compounds to study the effect of oxygen & nitrogen doping. Zhao et al [6] had earlier investigated experimentally the same two compounds La 3 InO & La 3 InN and concluded that while La 3 InO showed superconducting behavior at 10 K, La 3 InN showed no superconducting behavior above 2 K. Strychalska et al [7] in 2016 experimentally synthesized and studied the magnetic susceptibility, specific heat and electrical resistivity of La 3 Co & La 3 Ni and compared the electronic structure properties of both these compounds leading to the conclusion that La 3 Ni has lower T c than La 3 Co. In 2022 Hoffmann et al [8] studied conventional superconductivity in 397 antiperovskites materials among them InBLa 3 , InCLa 3 , InNLa 3 , InOLa 3 using machine learning models and concluded that λ is directly proportional to DOS at the Fermi surface & inversely proportional to the mass of Y-atom (XYZ 3 ).…”

Section: Introductionmentioning

confidence: 99%

Electron-phonon coupling in La₃In under pressure

Singh

Pinsook

2023

J. Phys.: Condens. Matter

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Conventional superconducting parameters Eliashberg spectral function, phonon DOS, average electron-phonon coupling constant & superconducting transition temperature of La3In were calculated at ambient and applied positive hydrostatic pressure. Ambient pressure electron-phonon coupling constant was found to be 1.43 and superconducting transition temperature was calculated to be 8.7 K which is close to the experimental reported value of 9.5 K. Logarithmic average phonon frequency at ambient pressure was found to be 6.21×10-3 eV. Phonon dispersion relations for the ambient and applied positive hydrostatic pressure were calculated to confirm the dynamical stability of La3In under positive pressure. Acoustic modes of vibrations were found to mediate most of the electron-phonon-electron interaction with a very small contribution from optical modes of vibrations. Fermi surface at ambient pressure was also calculated and employed in explaining the large value of the calculated electron-phonon coupling constant. The effect of spin-orbit coupling (SOC) on electronic, phonon and superconducting properties of La3In was also studied.

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