Encoding a Qubit into a Cavity Mode in Circuit-QED using Phase Estimation

TL;DR

This paper proposes a method to encode a qubit into a cavity mode in circuit-QED using phase estimation, enabling error-protected quantum information storage with realistic experimental feasibility.

Contribution

It introduces a practical protocol for creating Gottesman-Kitaev-Preskill states via phase estimation in circuit-QED, including detailed implementation and performance analysis.

Findings

Achieves 94% success probability in state preparation

Requires about 4 microseconds with 8 adaptive phase estimation rounds

Compatible with current experimental setups in circuit-QED

Abstract

Gottesman, Kitaev and Preskill have formulated a way of encoding a qubit into an oscillator such that the qubit is protected against small shifts (translations) in phase space. The idea underlying this encoding is that error processes of low rate can be expanded into small shift errors. The qubit space is defined as an eigenspace of two mutually commuting displacement operators $S_p$ and $S_q$ which act as large shifts/translations in phase space. We propose and analyze the approximate creation of these qubit states by coupling the oscillator to a sequence of ancilla qubits. This preparation of the states uses the idea of phase estimation where the phase of the displacement operator, say $S_p$, is approximately determined. We consider several possible forms of phase estimation. We analyze the performance of repeated and adapative phase estimation as the simplest and experimentally most viable schemes given a realistic upper-limit on the number of photons in the oscillator. We propose a detailed physical implementation of this protocol using the dispersive coupling between a transmon ancilla qubit and a cavity mode in circuit-QED. We provide an estimate that in a current experimental set-up one can prepare a good code state from a squeezed vacuum state using $8$ rounds of adapative phase estimation, lasting in total about $4 \mu$ sec., with $94\%$ (heralded) chance of success.