Quantum control in spintronics

TL;DR

This paper reviews recent advances in quantum control of spin systems in condensed matter, highlighting their potential for quantum computing, sensing, and information storage, and discusses various physical implementations and their capabilities.

Contribution

It provides a comprehensive overview of the state-of-the-art in quantum control of spins in condensed matter systems, emphasizing new experimental techniques and potential applications.

Findings

Individual electron spins can be manipulated and measured in GaAs and silicon.

Singlet-triplet states can be controlled in double-dot structures.

Spin states in nitrogen vacancy centres in diamond can be manipulated optically.

Abstract

Superposition and entanglement are uniquely quantum phenomena. Superposition incorporates a phase which contains information surpassing any classical mixture. Entanglement offers correlations between measurements in quantum systems that are stronger than any which would be possible classically. These give quantum computing its spectacular potential, but the implications extend far beyond quantum information processing. Early applications may be found in entanglement enhanced sensing and metrology. Quantum spins in condensed matter offer promising candidates for investigating and exploiting superposition and entanglement, and enormous progress is being made in quantum control of such systems. In GaAs, individual electron spins can be manipulated and measured, and singlet-triplet states can be controlled in double-dot structures. In silicon, individual electron spins can be detected by ionisation of phosphorous donors, and information can be transferred from electron spins to nuclear spins to provide long memory times. Electron and nuclear spins can be manipulated in nitrogen atoms incarcerated in fullerene molecules, which in turn can be assembled in ordered arrays. Spin states of charged nitrogen vacancy centres in diamond can be manipulated and read optically. Collective spin states in a range of materials systems offer scope for holographic storage of information. Conditions are now excellent for implementing superposition and entanglement in spintronic devices, thereby opening up a new era of quantum technologies.