Litcius/Paper detail

Fault-Tolerant Multiqubit Geometric Entangling Gates Using Photonic Cat-State Qubits

Ye‐Hong Chen, Roberto Stassi, Wei Qin, Adam Miranowicz, Franco Nori

2022Physical Review Applied36 citationsDOI

Abstract

We propose a theoretical protocol to implement multiqubit geometric gates (i.e., the M\o{}lmer-S\o{}rensen gate) using photonic cat-state qubits. These cat-state qubits stored in high-$Q$ resonators are promising for hardware-efficient universal quantum computing. Specifically, in the limit of strong two-photon drivings, phase-flip errors of the cat-state qubits are effectively suppressed, leaving only a bit-flip error to be corrected. Because this dominant error commutes with the evolution operator, our protocol preserves the error bias, and, thus, can lower the code-capacity threshold for error correction. A geometric evolution guarantees the robustness of the protocol against stochastic noise along the evolution path. Moreover, by changing detunings of the cavity-cavity couplings at a proper time, the protocol can be robust against parameter imperfections (e.g., the total evolution time) without introducing extra noises into the system. As a result, the gate can produce multimode entangled cat states in a short time with high fidelities.

Topics & Concepts

QubitPhysicsPhotonicsFault toleranceState (computer science)Quantum mechanicsComputer scienceQuantumAlgorithmDistributed computingQuantum Information and CryptographyQuantum Computing Algorithms and ArchitectureQuantum-Dot Cellular Automata