Phase Modulated Thermal Conductance of Josephson Weak Links
arXiv:cond-mat/0302346 · doi:10.1103/PhysRevLett.91.077003
Abstract
We present a theory for quasiparticle heat transport through superconducting weak links. The thermal conductance depends on the phase difference ($Ï$) of the superconducting leads. Branch conversion processes, low-energy Andreev bound states near the contact and the suppression of the local density of states near the gap edge are related to phase-sensitive transport processes. Theoretical results for the influence of junction transparency, temperature and disorder, on the phase modulation of the conductance are reported. For high-transmission weak links, $D\to 1$, the formation of an Andreev bound state at $ε_{\text{\tiny b}}=Î\cos(Ï/2)$ leads to suppression of the density of states for the continuum excitations that transport heat, and thus, to a reduction in the conductance for $Ï\simeqÏ$. For low-transmission ($D\ll 1$) barriers resonant scattering at energies $ε\simeq(1+D/2)Î$ leads to an increase in the thermal conductance as $T$ drops below $T_c$ (for phase differences near $Ï=Ï$).
4 pages, 3 figures Expanded discussion of boundary conditions for Ricatti amplitudes