Debye temperature, electron-phonon coupling constant, and three-dome shape of crystalline strain as a function of pressure in highly compressed La3Ni2O7-δ

Abstract

Besides ongoing studies of phase structural transitions, pairing mechanism, and physical properties of recently discovered highly compressed high-temperature superconductor La3Ni2O7-δ, here we explored a possibility for the electron-phonon pairing mechanism as an origin of the superconducting state and determined the microcrystalline strain, ε(P), in high pressure Fmmm-phase, and low-pressure Ammm-phase of this nickelate. To do this, we analyzed temperature dependent resistance and extracted pressure dependent Debye temperature, D(P), in La3Ni2O7-δ with an approximate value of D(P = 25 GPa) = 550 K. From this we established that the La3Ni2O7-δ is strong-coupled superconductor with the electron-phonon coupling constant λe-ph(P=22.4 GPa) = 1.75. This value is close to λe-ph = 1.70 of ambient pressure superconductors Nb3R (R = Sn, Al). To address ongoing discussion that the lattice strain can be the origin for the emergence of high-temperature superconductivity in the La3Ni2O7-δ, we determined the microcrystalline strain, 0.011 < ε(P), in the high-pressure Fmmm-phase, and ε(P) < 0.011 of low-pressure Fmmm-phase. Our analysis showed that ε(P) has three-dome shape in the pressure range of 1.6 GPa < P < 41.2 GPa. One of these two ε(P) deeps at P ≈ 15 GPa coincides with the pressure at which the Ammm-phase into the Fmmm-phase phase transition occurs. Based on our analysis, we proposed probable condition to observe the zero-resistance state in La3Ni2O7-δ.