Cooper pairing reexamined

Abstract

When both two-electron 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 real solutions E0BS= 2 ωD%/e2/λ +1 which coincide with the zero-temperature BCS energy gap = ωD/ (1/λ) in the weak coupling limit. Here, ωD is the Debye energy and λ ≥ 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-imaginary solutions assumed since at least the late 1950s as the only solutions, namely, E0BS= i2 ωD/e2/λ-1.