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Paper detail

Mechanical Purcell Filters for Microwave Quantum Machines

In circuit quantum electrodynamics, measuring the state of a superconducting qubit introduces a loss channel which can enhance spontaneous emission through the Purcell effect, thus decreasing qubit lifetime. This decay can be mitigated by performing the measurement through a Purcell filter which forbids signal propagation at the qubit transition frequency. If the filter is also well-matched at the readout cavity frequency, it will protect the qubit from decoherence channels without sacrificing measurement speed. We propose and analyze design for a mechanical Purcell filter, which we also fabricate and characterize at room temperature. The filter is comprised of an array of nanomechanical resonators in thin-film lithium niobate, connected in a ladder topology, with series and parallel resonances arranged to produce a bandpass response. The modest footprint, steep band edges, and absence of cross-talk in these filters make them a novel and appealing alternative to analogous electromagnetic versions currently used in microwave quantum machines.

preprint2019arXivOpen access
Agnetta Y. ClelandMarek PechalPieter-Jan C. StasChristopher J. SarabalisAmir H. Safavi-Naeini
quant-ph
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Agnetta Y. ClelandMarek PechalPieter-Jan C. StasChristopher J. SarabalisAmir H. Safavi-Naeini

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