# Antiadiabatic Phonons and Superconductivity in Eliashberg-McMillan   Theory

**Authors:** M.V. Sadovskii

arXiv: 1908.00718 · 2020-02-03

## TL;DR

This paper extends Eliashberg-McMillan theory to non-adiabatic and antiadiabatic regimes, analyzing how high-frequency phonons influence superconductivity, and derives a general formula for the transition temperature in these conditions.

## Contribution

It introduces a modified coupling constant for non-adiabatic regimes and derives a new expression for $T_c$ considering antiadiabatic phonons, expanding the theory beyond the adiabatic approximation.

## Key findings

- Mass renormalization is governed by a different coupling constant in non-adiabatic regimes.
- In the antiadiabatic limit, corrections to electronic spectrum become negligible.
- Superconducting transition temperature $T_c$ depends on the Eliashberg coupling constant even when phonons are antiadiabatic.

## Abstract

The standard Eliashberg - McMillan theory of superconductivity is essentially based on the adiabatic approximation. Here we present some simple estimates of electron - phonon interaction within Eliashberg - McMillan approach in non - adiabatic and even antiadiabatic situation, when characteristic phonon frequency $\Omega_0$ becomes large enough, i.e. comparable or exceeding the Fermi energy $E_F$. We discuss the general definition of Eliashberg - McMillan (pairing) electron - phonon coupling constant $\lambda$, taking into account the finite value of phonon frequencies. We show that the mass renormalization of electrons is in general determined by different coupling constant $\tilde\lambda$, which takes into account the finite width of conduction band, and describes the smooth transition from the adiabatic regime to the region of strong nonadiabaticity. In antiadiabatic limit, when $\Omega_0\gg E_F$, the new small parameter of perturbation theory is $\lambda\frac{E_F}{\Omega_0}\sim\lambda\frac{D}{\Omega_0}\ll 1$ ($D$ is conduction band half -- width), and corrections to electronic spectrum (mass renormalization) become irrelevant. However, the temperature of superconducting transition $T_c$ in antiadiabatic limit is still determined by Eliashberg - McMillan coupling constant $\lambda$. We consider in detail the model with discrete set of (optical) phonon frequencies. A general expression for superconducting transition temperature $T_c$ is derived, which is valid in situation, when one (or several) of such phonons becomes antiadiabatic. We also analyze the contribution of such phonons into the Coulomb pseudopotential $\mu^{\star}$ and show, that antiadiabatic phonons do not contribute to Tolmachev's logarithm and its value is determined by partial contributions from adiabatic phonons only.

## Full text

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## Figures

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## References

24 references — full list in the complete paper: https://tomesphere.com/paper/1908.00718/full.md

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Source: https://tomesphere.com/paper/1908.00718