Dispersive readout scheme for a Josephson phase qubit

TL;DR

This paper introduces a dispersive readout method for Josephson phase qubits using a nonlinear resonator, enabling faster, low-dissipation measurements and potential multiplexing of multiple qubits.

Contribution

The paper presents an experimental dispersive readout scheme for Josephson phase qubits using a capacitively shunted SQUID as a nonlinear resonator, improving speed and enabling multiplexing.

Findings

Reduced measurement time to 25 microseconds.

Demonstrated low-dissipative, non-destructive readout.

Enabled frequency-division multiplexing for multiple qubits.

Abstract

We present experimental results on a dispersive scheme for reading out a Josephson phase qubit. A capacitively shunted dc-SQUID is used as a nonlinear resonator which is inductively coupled to the qubit. We detect the flux state of the qubit by measuring the amplitude and phase of a microwave pulse reflected from the SQUID resonator. By this low-dissipative method, we reduce the qubit state measurement time down to 25 microseconds, which is much faster than using the conventional readout performed by switching the SQUID to its non-zero dc voltage state. The demonstrated readout scheme allows for reading out multiple qubits using a single microwave line by employing frequency-division multiplexing.