High-sensitivity AC-charge detection with a MHz-frequency fluxonium
qubit
- URL: http://arxiv.org/abs/2307.14329v1
- Date: Wed, 26 Jul 2023 17:48:09 GMT
- Title: High-sensitivity AC-charge detection with a MHz-frequency fluxonium
qubit
- Authors: B.-L. Najera-Santos, R. Rousseau, K. Gerashchenko, H. Patange, A.
Riva, M. Villiers, T. Briant, P.-F. Cohadon, A. Heidmann, J. Palomo, M.
Rosticher, H. le Sueur, A. Sarlette, W. C. Smith, Z. Leghtas, E. Flurin, T.
Jacqmin, S. Del\'eglise
- Abstract summary: We operate a heavy fluxonium with an unprecedentedly low transition frequency of $1.8mathrm$$.
By directly addressing the qubit transition with a capacitively coupled waveguide, we showcase its high sensitivity to a radio-frequency field.
This method results in a charge sensitivity of $33mumathrme/sqrtmathrmHz$, or an energy sensitivity (in joules per hertz) of $2.8hbar.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Owing to their strong dipole moment and long coherence times, superconducting
qubits have demonstrated remarkable success in hybrid quantum circuits.
However, most qubit architectures are limited to the GHz frequency range,
severely constraining the class of systems they can interact with. The
fluxonium qubit, on the other hand, can be biased to very low frequency while
being manipulated and read out with standard microwave techniques. Here, we
design and operate a heavy fluxonium with an unprecedentedly low transition
frequency of $1.8~\mathrm{MHz}$. We demonstrate resolved sideband cooling of
the ``hot'' qubit transition with a final ground state population of $97.7~\%$,
corresponding to an effective temperature of $23~\mu\mathrm{K}$. We further
demonstrate coherent manipulation with coherence times $T_1=34~\mu\mathrm{s}$,
$T_2^*=39~\mu\mathrm{s}$, and single-shot readout of the qubit state.
Importantly, by directly addressing the qubit transition with a capacitively
coupled waveguide, we showcase its high sensitivity to a radio-frequency field.
Through cyclic qubit preparation and interrogation, we transform this
low-frequency fluxonium qubit into a frequency-resolved charge sensor. This
method results in a charge sensitivity of
$33~\mu\mathrm{e}/\sqrt{\mathrm{Hz}}$, or an energy sensitivity (in joules per
hertz) of $2.8~\hbar$. This method rivals state-of-the-art transport-based
devices, while maintaining inherent insensitivity to DC charge noise. The high
charge sensitivity combined with large capacitive shunt unlocks new avenues for
exploring quantum phenomena in the $1-10~\mathrm{MHz}$ range, such as the
strong-coupling regime with a resonant macroscopic mechanical resonator.
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