Implementation of hybridly protected quantum gates

TL;DR

This paper proposes a hybrid approach to implementing protected quantum gates that combines holonomy, dynamical decoupling, and dephasing-free features, using a simple spin model suitable for near-term quantum devices.

Contribution

It introduces a novel scheme for protected quantum operations that is experimentally feasible, resource-efficient, and adaptable to various physical systems for quantum computing.

Findings

Scheme is based on an experimentally achievable Hamiltonian.

Reduces computational resource requirements.

Suitable for near-term quantum devices.

Abstract

We explore the implementation of hybridly protected quantum operations combining the merits of holonomy, dynamical decoupling approach and dephasing-free feature based on a simple and experimentally achievable spin model. The implementation of the quantum operations can be achieved in different physical systems with controllable parameters. The protected quantum operations are hence controllable, well-suited for resolving various quantum computation tasks, such as executing quantum error-correction codes or quantum error mitigation. Our scheme is based on experimentally achievable Hamiltonian with reduced requirement of computational resources and thus, it brings us closer towards realizing protected quantum operations for resolving quantum computation tasks in near-term quantum devices.