Nature Communications (Nov 2023)

Experimental realisation of multi-qubit gates using electron paramagnetic resonance

  • Edmund J. Little,
  • Jacob Mrozek,
  • Ciarán J. Rogers,
  • Junjie Liu,
  • Eric J. L. McInnes,
  • Alice M. Bowen,
  • Arzhang Ardavan,
  • Richard E. P. Winpenny

DOI
https://doi.org/10.1038/s41467-023-42169-7
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 12

Abstract

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Abstract Quantum information processing promises to revolutionise computing; quantum algorithms have been discovered that address common tasks significantly more efficiently than their classical counterparts. For a physical system to be a viable quantum computer it must be possible to initialise its quantum state, to realise a set of universal quantum logic gates, including at least one multi-qubit gate, and to make measurements of qubit states. Molecular Electron Spin Qubits (MESQs) have been proposed to fulfil these criteria, as their bottom-up synthesis should facilitate tuning properties as desired and the reproducible production of multi-MESQ structures. Here we explore how to perform a two-qubit entangling gate on a multi-MESQ system, and how to readout the state via quantum state tomography. We propose methods of accomplishing both procedures using multifrequency pulse Electron Paramagnetic Resonance (EPR) and apply them to a model MESQ structure consisting of two nitroxide spin centres. Our results confirm the methodological principles and shed light on the experimental hurdles which must be overcome to realise a demonstration of controlled entanglement on this system.