Solvable Strong-coupling Quantum Dot Model with a Non-Fermi-liquid Pairing Transition
Abstract
We show that a random interacting model exhibits solvable non-Fermi liquid behavior and exotic pairing behavior. This model, dubbed as the Yukawa-SYK model, describes the random Yukawa coupling between quantum dots each hosting flavors of fermions and bosons that self-tunes to criticality at low energies. The diagrammatic expansion is controlled by , and the results become exact in a large-, large- limit. We find that pairing only develops within a region of the plane --- even though the pairing interaction is strongly attractive, the incoherence of the fermions can spoil the forming of Cooper pairs, rendering the system a non-Fermi liquid down to zero temperature. By solving the Eliashberg equation and the renormalization group equation, we show that the transition into the pairing phase exhibits Kosterlitz-Thouless quantum-critical behavior.
Cite
@article{arxiv.1904.07240,
title = {Solvable Strong-coupling Quantum Dot Model with a Non-Fermi-liquid Pairing Transition},
author = {Yuxuan Wang},
journal= {arXiv preprint arXiv:1904.07240},
year = {2020}
}
Comments
Click "ancillary files" on the right panel for the supplemental material. A new title per editors' request; to appear on PRL; 6 pages, 2 figures