Low temperature-semiconductor band gap thermal shifts: T4 shifts from ordinary acoustic and T2 from piezoacoustic coupling

Abstract

At low temperature T, the experimental gap of silicon decreases as Eg(T)=Eg(0)-AT4. The main reason is electron-phonon renormalization. The physics behind the T4-power law is more complex than has been realized. Renormalization by intraband scattering requires a careful non-adiabatic treatment in order to correctly include acoustic phonons and avoid divergences from piezoacoustic phonon interactions. The result is an unexpected low T term Eg(0)+A' Tp with positive coefficient A', and power p=4 for non-piezoelectric materials, and power p=2 for piezoelectric materials. The acoustic phonons in piezoelectric semiconductors generate a piezoelectric field, modifying the electron-phonon coupling. However, at higher T, when thermal acoustic phonons of energy hbar vs q acquire energies comparable to the electronic intermediate state (higher than the band-edge state by hbar2 q2 /2m*), the low q and higher q intraband contributions to Tp rapidly cancel, giving little thermal effect. But there is an additional T-dependence from interband effects of acoustic phonons. This turns out to have power law T4 for both non-piezoelectric and piezoelectric semiconductors. This term can have either sign, but usually reduces the size of gaps as T increases. It arises after cancellation of the T2 terms that appear separately in Debye-Waller and Fan parts of the acoustic phonon interband renormalization. The cancellation occurs because of the acoustic sum rule.