Manipulating phonons of a trapped-ion system using optical tweezers

TL;DR

This paper introduces a method to control phonon modes in trapped-ion systems using optical tweezers, enabling programmable quantum simulations and improved quantum information processing.

Contribution

It proposes an experimental setup with optical tweezers for site-dependent control of ion phonons, enhancing quantum simulation and computation capabilities.

Findings

Protocols for high-accuracy phonon mode programming

Applications in quantum thermodynamics and sympathetic cooling

Discussion of optical parameters and potential adverse effects

Abstract

We propose an experimental architecture where an array of optical tweezers affords site-dependent control over the confining potential of a conventional radio-frequency ion trap. The site-dependent control enables programmable manipulation of phonon modes of ions, with many potential applications in quantum information processing (QIP) and thermodynamics. We describe protocols for programming the array of optical tweezers to attain a set of target phonon modes with high accuracy. We propose applications of such controls in simulating quantum thermodynamics of a particle of programmable effective mass via Jarzynski's equality and improving the efficiency of sympathetic cooling and quantum logic gates in a multi-species ion system of disparate masses. We discuss the required optical parameters in a realistic ion trap system and potential adverse effects of optical tweezers in QIP. Our scheme extends the utility of trapped-ions as a platform for quantum computation and simulation.