Personal profile
Research interests
I am investigating how quantum information techniques can be used to probe the nature of gravitational interactions in quantum systems. Specifically this involves exploring how entanglement, squeezing, or non-Gaussianity arises in optomechanical systems such as photon cavities and laser interferometers as well as cold matter systems such as Bose Einstein condensates and superfluid Helium.
Research interests (continued)
I also have a strong interest in quantum compuitng and quantum algorithms. I have worked previously on quantum cryptography projects which involved designing quantum circuits for attacks on RSA encryption. Currently I am interested in the link between non-Gaussianity and quantum advantage for computation.
Education/Academic qualification
Quantum Physics, University of Nottingham
Award Date: 1 Sept 2022
Theoretical Physics, University of Birmingham
Award Date: 1 Jun 2020
Keywords
- Quantum mechanics
- Quantum Information Science
- Quantum computing
- Quantum Optics
- Quantum devices
- Quantum gravity
- Quantum Cryptography
- Cold Atoms
- Bose Einstein Condensates
- Superfluid Helium
- Superconducting Quantum Circuits
Research output
- 1 Article
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Classical theories of gravity produce entanglement
Aziz, J. & Howl, R., 22 Oct 2025, In: Nature. 646, p. 813-817 5 p.Research output: Contribution to journal › Article › peer-review
Open Access