TY - JOUR
T1 - Quantum probe of an on-chip broadband interferometer for quantum microwave photonics
AU - Eder, P.
AU - Ramos, T.
AU - Goetz, J.
AU - Fischer, M.
AU - Pogorzalek, S.
AU - Martinez, J. Puertas
AU - Menzel, E. P.
AU - Loacker, F.
AU - Xie, E.
AU - Garcia-Ripoll, J. J.
AU - Fedorov, K. G.
AU - Marx, A.
AU - Deppe, F.
AU - Gross, R.
N1 - Publisher Copyright:
© 2018 IOP Publishing Ltd.
PY - 2018/9/17
Y1 - 2018/9/17
N2 - Quantum microwave photonics aims at generating, routing, and manipulating propagating quantum microwave fields in the spirit of optical photonics. To this end, the strong nonlinearities of superconducting quantum circuits can be used to either improve or move beyond the implementation of concepts from the optical domain. In this context, the design of a well-controlled broadband environment for the superconducting quantum circuits is a central task. In this work, we place a superconducting transmon qubit in one arm of an on-chip Machehnder interferometer composed of two superconducting microwave beam splitters. By measuring its relaxation and dephasing rates we use the qubit as a sensitive spectrometer at the quantum level to probe the broadband electromagnetic environment. For frequencies near the qubit transition frequency, this environment can be well described by an ensemble of harmonic oscillators coupled to the transmon qubit. At low frequencies ω → 0, we find experimental evidence for colored quasi-static Gaussian noise with a high spectral weight, as it is typical for ensembles of two-level fluctuators. Our work paves the way towards possible applications of propagating microwave photons, such as emulating quantum impurity models or a novel architecture for quantum information processing.
AB - Quantum microwave photonics aims at generating, routing, and manipulating propagating quantum microwave fields in the spirit of optical photonics. To this end, the strong nonlinearities of superconducting quantum circuits can be used to either improve or move beyond the implementation of concepts from the optical domain. In this context, the design of a well-controlled broadband environment for the superconducting quantum circuits is a central task. In this work, we place a superconducting transmon qubit in one arm of an on-chip Machehnder interferometer composed of two superconducting microwave beam splitters. By measuring its relaxation and dephasing rates we use the qubit as a sensitive spectrometer at the quantum level to probe the broadband electromagnetic environment. For frequencies near the qubit transition frequency, this environment can be well described by an ensemble of harmonic oscillators coupled to the transmon qubit. At low frequencies ω → 0, we find experimental evidence for colored quasi-static Gaussian noise with a high spectral weight, as it is typical for ensembles of two-level fluctuators. Our work paves the way towards possible applications of propagating microwave photons, such as emulating quantum impurity models or a novel architecture for quantum information processing.
KW - circuit QED
KW - decoherence scattering
KW - propagating quantum microwaves
KW - quantum microwave photonics
KW - superconducting circuits
KW - transmon qubit
UR - http://www.scopus.com/inward/record.url?scp=85055329928&partnerID=8YFLogxK
U2 - 10.1088/1361-6668/aad8f4
DO - 10.1088/1361-6668/aad8f4
M3 - Article
AN - SCOPUS:85055329928
SN - 0953-2048
VL - 31
JO - Superconductor Science and Technology
JF - Superconductor Science and Technology
IS - 11
M1 - 115002
ER -