Quantum Information Processing with Molecular Nanomagnets: an introduction

TL;DR

This paper introduces quantum information processing using molecular nanomagnets, discussing their potential for quantum algorithms, error correction, and recent experimental implementations in a promising molecular spin architecture.

Contribution

It provides an overview of molecular nanomagnets for quantum computing, including design principles, noise sources, multi-state encoding, and recent experimental quantum algorithms.

Findings

Molecular nanomagnets can encode quantum information in multiple states.

Error correction schemes can be implemented in molecular spin systems.

Quantum algorithms have been proposed and experimentally realized on this hardware.

Abstract

Many problems intractable on classical devices could be solved by algorithms explicitly based on quantum mechanical laws, i.e. exploiting quantum information processing. As a result, increasing efforts from different fields are nowadays directed to the actual realization of quantum devices. Here we provide an introduction to Quantum Information Processing, focusing on a promising setup for its implementation, represented by molecular spin clusters known as Molecular Nanomagnets. We introduce the basic tools to understand and design quantum algorithms, always referring to their actual realization on a molecular spin architecture. We then examine the most important sources of noise in this class of systems and then one of their most peculiar features, i.e. the possibility to exploit many (more than two) available states to encode information and to self-correct it from errors via proper design of quantum error correction codes. Finally, we present some examples of quantum algorithms proposed and implemented on a molecular spin qudit hardware.