Photon-assisted tunneling with non-classical light
Abstract
Among the most exciting recent advances in the field of superconducting quantum circuits is the ability to coherently couple microwave photons in low-loss cavities to quantum electronic conductors (e.g.~semiconductor quantum dots or carbon nanotubes). These hybrid quantum systems hold great promise for quantum information processing applications; even more strikingly, they enable exploration of completely new physical regimes. Here we study theoretically the new physics emerging when a quantum electronic conductor is exposed to non-classical microwaves (e.g.~squeezed states, Fock states). We study this interplay in the experimentally-relevant situation where a superconducting microwave cavity is coupled to a conductor in the tunneling regime. We find the quantum conductor acts as a non-trivial probe of the microwave state; in particular, the emission and absorption of photons by the conductor is characterized by a non-positive definite quasi-probability distribution. This negativity has a direct influence on the conductance of the conductor.
Cite
@article{arxiv.1408.1128,
title = {Photon-assisted tunneling with non-classical light},
author = {J. -R. Souquet and M. J. Woolley and Julien Gabelli and Pascal Simon and Aashish A. Clerk},
journal= {arXiv preprint arXiv:1408.1128},
year = {2014}
}
Comments
8 pages, 5 figures; Supplementary Information: 12 pages 8 figures