Prof Jonathan Jones

Witnesses of non-classicality for simulated hybrid quantum systems

Journal of Physics Communications IOP Publishing 4:2 (2020) 025013

Authors:

Jonathan A Jones, Gaurav Bhole, Chiara Marletto, Vlatko Vedral

Abstract:

The task of testing whether quantum theory applies to all physical systems and all scales requires considering situations where a quantum probe interacts with another system that need not obey quantum theory in full. Important examples include the cases where a quantum mass probes the gravitational field, for which a unique quantum theory of gravity does not yet exist, or a quantum field, such as light, interacts with a macroscopic system, such as a biological molecule, which may or may not obey unitary quantum theory. In this context a class of experiments has recently been proposed, where the non-classicality of a physical system that need not obey quantum theory (the gravitational field) can be tested indirectly by detecting whether or not the system is capable of entangling two quantum probes. Here we illustrate some of the subtleties of the argument, to do with the role of locality of interactions and of non-classicality, and perform proof-of-principle experiments illustrating the logic of the proposals, using a Nuclear Magnetic Resonance quantum computational platform with four qubits.

A robust entangling gate for polar molecules using magnetic and microwave fields

(2019)

Authors:

Michael Hughes, Matthew D Frye, Rahul Sawant, Gaurav Bhole, Jonathan A Jones, Simon L Cornish, MR Tarbutt, Jeremy M Hutson, Dieter Jaksch, Jordi Mur-Petit

Rescaling interactions for quantum control

(2019)

Authors:

Gaurav Bhole, Takahiro Tsunoda, Peter J Leek, Jonathan A Jones

Witnesses of non-classicality for simulated hybrid quantum systems

(2018)

Authors:

Gaurav Bhole, Jonathan A Jones, Chiara Marletto, Vlatko Vedral

Practical pulse engineering: Gradient ascent without matrix exponentiation

Frontiers of Physics Springer Verlag 13:3 (2018) 130312

Authors:

Gaurav Bhole, Jonathan Jones

Abstract:

Since 2005, there has been a huge growth in the use of engineered control pulses to perform desired quantum operations in systems such as nuclear magnetic resonance quantum information processors. These approaches, which build on the original gradient ascent pulse engineering algorithm, remain computationally intensive because of the need to calculate matrix exponentials for each time step in the control pulse. In this study, we discuss how the propagators for each time step can be approximated using the Trotter–Suzuki formula, and a further speedup achieved by avoiding unnecessary operations. The resulting procedure can provide substantial speed gain with negligible costs in the propagator error, providing a more practical approach to pulse engineering.