We analyze the measurement crosstalk between two flux-biased phase qubits
coupled by a resonant coplanar waveguide cavity. After the first qubit is
measured, the superconducting phase can undergo damped oscillations resulting
in an a.c. voltage that produces a frequency chirped noise signal whose
frequency crosses that of the cavity. We show experimentally that the coplanar
waveguide cavity acts as a bandpass filter that can significantly reduce the
crosstalk signal seen by the second qubit when its frequency is far from the
cavity's resonant frequency. We present a simple classical description of the
qubit behavior that agrees well with the experimental data. These results
suggest that measurement crosstalk between superconducting phase qubits can be
reduced by use of linear or possibly nonlinear resonant cavities as coupling
elements.Comment: 4 pages, 3 figure

Allman, Michael S.

Altomare, Fabio

Cicak, Katarina

Li, Dale

Park, Jae I.

Sillanpää, Mika A.

Simmonds, Raymond W.

Sirois, Adam J.

Strong, Joshua A.

Teufel, John D.

Whittaker, Jed D.

Physical Review B

English

arXiv

We investigate measurement crosstalk in a system with two flux-biased phase qubits coupled by a resonant coplanar waveguide cavity. After qubit measurement, the superconducting phase undergoes damped oscillations in a deep anharmonic potential producing a frequency chirped voltage or crosstalk signal. We show experimentally that a coplanar waveguide cavity acts as a bandpass filter that can significantly reduce the propagation of this crosstalk signal when the qubits are far off resonance from the cavity. The transmission of the crosstalk signal ∝(ωqCx)2 can be further minimized by reducing the qubit frequencies and the coupling capacitance to the cavity. We model the large amplitude crosstalk signal and qubit response classically with results that agree well with the experimental data. We find that the maximum energy transferred by the crosstalk generating qubit roughly saturates for long energy relaxation times (T1>100 ns) while the delay time necessary for the crosstalk signal to propagate to the cavity scales linearly with T1. Ultimately, the use of resonant cavities as coupling elements and crosstalk filters is extremely beneficial for future architectures incorporating many coupled qubits.Peer reviewe

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Measurement crosstalk between two phase qubits coupled by a coplanar waveguide

Fabio Altomare

Katarina Cicak

Mika A. Sillanpää

Michael S. Allman

Adam J. Sirois

Dale Li

Jae I. Park

Joshua A. Strong

John D. Teufel

Jed D. Whittaker

Raymond W. Simmonds

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Measurement crosstalk between two phase qubits coupled by a coplanar
  waveguide

Measurement crosstalk between two phase qubits coupled by a coplanar waveguide

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