The characterization of high-pressure superconducting state in Si2H6 compound: the strong-coupling description

Abstract: The thermodynamic parameters of the superconducting state, that induces in ${\rm Si_{2}H_{6}}$ under the pressure at 275 GPa, have been calculated. In the framework of the Eliashberg formalism, it has been shown that the critical temperature can attain extremely high values: $T_{C}(\mu^{\star})\in<173.36, 99.99>$ K, where the Coulomb pseudopotential $(\mu^{\star})$ belongs to the range from 0.1 to 0.3. The ratio of the energy gap to the critical temperature ($R_{\Delta}$) significantly exceeds the value predicted by the BCS theory: $R_{\Delta}(\mu^{\star})\in<4.40, 4.04>$. Additionally, it has been stated that in the whole range of the superconducting state's existence, the electron effective mass ($m^{\star}_{e}$) is large; $[m^{\star}_{e}]^{\rm max}{T=T{C}}=2.397m_{e}$, where the symbol $m_{e}$ denotes the electron band mass.