6533b863fe1ef96bd12c782c
RESEARCH PRODUCT
Local Sensing with the Multi-Level AC Stark Effect
Michael MarthalerMichael MarthalerJochen BraumüllerAndre SchneiderPatrizia StehleHannes RotzingerLingzhen GuoMartin WeidesAlexey V. UstinovAlexey V. Ustinovsubject
PhysicsQuantum PhysicsPhotonCondensed Matter - SuperconductivityOrder (ring theory)FOS: Physical sciences02 engineering and technologyTransmonPhoton energy021001 nanoscience & nanotechnology01 natural sciencesSuperconductivity (cond-mat.supr-con)symbols.namesakeStark effectQubit0103 physical sciencessymbolsSensitivity (control systems)Atomic physics010306 general physics0210 nano-technologyQuantum Physics (quant-ph)Energy (signal processing)description
Analyzing weak microwave signals in the GHz regime is a challenging task if the signal level is very low and the photon energy widely undefined. A superconducting qubit can detect signals in the low photon regime, but due to its discrete level structure, it is only sensitive to photons of certain energies. With a multi-level quantum system (qudit) in contrast, the unknown signal frequency and amplitude can be deduced from the higher level AC Stark shift. The measurement accuracy is given by the signal amplitude, its detuning from the discrete qudit energy level structure and the anharmonicity. We demonstrate an energy sensitivity in the order of $10^{-3}$ with a measurement range of more than $1\,\mathrm{GHz}$. Here, using a transmon qubit, we experimentally observe shifts in the transition frequencies involving up to three excited levels. These shifts are in good agreement with an analytic circuit model and master equation simulations. For large detunings, we find the shifts to scale linearly with the power of the applied microwave drive. Exploiting the effect, we demonstrated a power meter which makes it possible to characterize the microwave transmission from source to sample.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2018-06-22 |