Dissipative optomechanical preparation of macroscopic quantum superposition states

TL;DR

This paper presents a deterministic method to generate macroscopic quantum superpositions in mechanical systems using dissipative state preparation, with a specific superconducting circuit implementation and verification scheme.

Contribution

It introduces a novel dissipative approach for creating long-lived spatial superpositions in macroscopic mechanical objects, advancing quantum-to-classical transition studies.

Findings

Successful design of a double-well potential for mechanical motion

Proposal for optomechanical sideband cooling to achieve superpositions

Method to verify mechanical states via superconducting qubits

Abstract

The transition from quantum to classical physics remains an intensely debated question even though it has been investigated for more than a century. Further clarifications could be obtained by preparing macroscopic objects in spatial quantum superpositions and proposals for generating such states for nano-mechanical devices either in a transient or a probabilistic fashion have been put forward. Here we introduce a method to deterministically obtain spatial superpositions of arbitrary lifetime via dissipative state preparation. In our approach, we engineer a double-well potential for the motion of the mechanical element and drive it towards the ground state, which shows the desired spatial superposition, via optomechanical sideband cooling. We propose a specific implementation based on a superconducting circuit coupled to the mechanical motion of a lithium-decorated monolayer graphene sheet, introduce a method to verify the mechanical state by coupling it to a superconducting qubit, and discuss its prospects for testing collapse models for the quantum to classical transition.