Superconducting quantum devices

Quantum dot admittance probed at microwave frequencies with an on-chip resonator

(2012)

Authors:

T Frey, PJ Leek, M Beck, J Faist, A Wallraff, K Ensslin, T Ihn, M Büttiker

Dipole Coupling of a Double Quantum Dot to a Microwave Resonator

PHYSICAL REVIEW LETTERS 108:4 (2012) ARTN 046807

Authors:

T Frey, PJ Leek, M Beck, A Blais, T Ihn, K Ensslin, A Wallraff

Dipole coupling of a double quantum dot to a microwave resonator

(2011)

Authors:

T Frey, PJ Leek, M Beck, A Blais, T Ihn, K Ensslin, A Wallraff

Characterization of a microwave frequency resonator via a nearby quantum dot

(2011)

Authors:

T Frey, PJ Leek, M Beck, K Ensslin, A Wallraff, T Ihn

Correlation measurements of individual microwave photons emitted from a symmetric cavity

Journal of Physics: Conference Series 264:1 (2011)

Authors:

D Bozyigit, C Lang, L Steffen, JM Fink, C Eichler, M Baur, R Bianchetti, PJ Leek, S Filipp, A Wallraff, MP Da Silva, A Blais

Abstract:

Superconducting circuits have been successfully established as systems to prepare and investigate microwave light fields at the quantum level. In contrast to optical experiments where light is detected using photon counters, microwaves are usually measured with well developed linear amplifiers. This makes measurements of correlation functions - one of the important tools in optics - harder to achieve because they traditionally rely on photon counters and beam splitters. Here, we demonstrate a system where we can prepare on demand single microwave photons in a cavity and detect them at the two outputs of the cavity using linear amplifiers. Together with efficient data processing, this allows us to measure different observables of the cavity photons, including the first-order correlation function. Using these techniques we demonstrate cooling of a thermal background field in the cavity. © Published under licence by IOP Publishing Ltd.