Scaling Phononic Quantum Networks of Solid-State Spins with Closed Mechanical Subsystems

TL;DR

This paper proposes a novel architecture for phononic quantum networks using closed mechanical subsystems in diamond nanostructures, enabling scalable and robust solid-state quantum communication.

Contribution

It introduces a new network design that partitions large mechanical systems into small, closed subsystems, overcoming scaling and chiral phononic process challenges in solid-state platforms.

Findings

Demonstrates a diamond phononic nanostructure with alternating waveguides and bandgaps.

Develops phonon-assisted state transfer protocols resilient to thermal noise.

Provides a scalable architecture for solid-state quantum networks.

Abstract

Phononic quantum networks feature distinct advantages over photonic networks for on-chip quantum communications, providing a promising platform for developing quantum computers with robust solid-state spin qubits. Large mechanical networks including one-dimensional chains of trapped ions, however, have inherent and well-known scaling problems. In addition, chiral phononic processes, which are necessary for conventional phononic quantum networks, are difficult to implement in a solid-state system. To overcome these seemingly unsolvable obstacles, we have developed a new network architecture that breaks a large mechanical network into small and closed mechanical subsystems. This architecture is implemented in a diamond phononic nanostructure featuring alternating phononic crystal waveguides with specially-designed bandgaps. The implementation also includes nanomechanical resonators coupled to color centers through phonon-assisted transitions as well as quantum state transfer protocols that can be robust against the thermal environment.