Theory of Superconducting Tc of doped fullerenes
Abstract
We develop the nonadiabatic polaron theory of superconductivity of MxC60 taking into account the polaron band narrowing and realistic electron-phonon and Coulomb interactions. We argue that the crossover from the BCS weak-coupling superconductivity to the strong-coupling polaronic and bipolaronic superconductivity occurs at the BCS coupling constant λ 1 independent of the adiabatic ratio, and there is nothing ``beyond'' Migdal's theorem except small polarons for any realistic electron-phonon interaction. By the use of the polaronic-type function and the ``exact'' diagonalization in the truncated Hilbert space of vibrons (``phonons'') we calculate the ground state energy and the electron spectral density of the C60- molecule. This allows us to describe the photoemission spectrum of C60- in a wide energy region and determine the electron-phonon interaction. The strongest coupling is found with the high-frequency pinch Ag2 mode and with the Frenkel exciton. We clarify the crucial role of high-frequency bosonic excitations in doped fullerenes which reduce the bare bandwidth and the Coulomb repulsion allowing the intermediate and low-frequency phonons to couple two small polarons in a Cooper pair. The Eliashberg-type equations are solved for low-frequency phonons. The value of the superconducting Tc, its pressure dependence and the isotope effect are found to be in a remarkable agreement with the available experimental data.
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