Cooper pairing reexamined
arXiv:0806.3492
Abstract
When both two-electron \textit{and} two-hole Cooper-pairing are treated on an equal footing in the ladder approximation to the Bethe-Salpeter (BS) equation, the zero-total-momentum Cooper-pair energy is found to have two \textit{real} solutions $\mathcal{E}_{0}^{BS}=\pm 2\hbar Ï_{{D}%}/\sqrt{{e}^{2/λ}+{1}}$ which coincide with the zero-temperature BCS energy gap $Î=\hbar Ï_{D}/\sinh (1/λ) $ in the weak coupling limit. Here, $\hbar Ï_{D}$ is the Debye energy and $λ\geq 0$ the BCS model interaction coupling parameter. The interpretation of the BCS energy gap as the binding energy of a Cooper-pair is often claimed in the literature but, to our knowledge, never substantiated even in weak-coupling as we find here. In addition, we confirm the two purely-\textit{imaginary} solutions assumed since at least the late 1950s as the \textit{only} solutions, namely, $\mathcal{E}_{0}^{BS}=\pm i2\hbar Ï_{D}/\sqrt{{e}^{2/λ}{-1}}.$
5 pages and 2 figures. Submitted for publication