STAFF PROFILE
Professor Jared Cole
Position:
Professor
College / Portfolio:
STEM College
School / Department:
STEM|School of Science
Phone:
+61399259555
Email:
jared.cole@rmit.edu.au
Campus:
City Campus
Contact me about:
Research supervision
Professor Jared Cole is a member of the Physics discipline of the School of Science and leader of the Theoretical Chemical and Quantum Physics research group.
He is a theoretical physicist, specialising in quantum theory and its application in electronics, computing and condensed-matter physics.Jared has extensive collaborations with both theoretical and experimental researchers overseas and within Australia. He has also taught various physics subjects at undergraduate and graduate level, both in Australia and Germany.
His current research interests include quantum circuit theory, spin physics, decoherence, measurement and entanglement theory, quantum information and computing.
Research interests
- Quantum coherence in low-temperature electronics and spin systems.
- Quantum computing and quantum information, especially in a solid-state context.
- The use of quantum circuits for applications in quantum computing and quantum metrology.
- Quantum sensing and using induced decoherence as a probe of dissipative environments.
- The interplay between atom-photon interactions and many-body physics.
Publications
The latest publications, including those currently under peer-review, are available on the arXiv.
View Associate Professor Jared Cole's full publication and ORCID.
Previous Academic Experience
- 2009 – 2010 Faculty Researcher, Karlsruhe Institute of Technology, Karlsruhe, Germany
- 2008 – 2009 Alexander von Humboldt Fellow, University of Karlsruhe, Karlsruhe, Germany
- 2006 – 2007 Research Fellow, ARC Centre for Quantum Computer Technology, University of Melbourne
- 2006 PhD, School of Physics, University of Melbourne
- 2002 B. App. Phys. / B. Comm. Eng. (Hons) RMIT University
- Klymenko, M.,Vaitkus, J.,Smith, J.,Cole, J. (2021). NanoNET: An extendable Python framework for semi-empirical tight-binding models In: Computer Physics Communications, 259, 1 - 13
- Andersson, G.,Bilobran, A.,Scigliuzzo, M.,De Lima, M.,Cole, J.,Delsing, P. (2021). Acoustic spectral hole-burning in a two-level system ensemble In: npj Quantum Information, 7, 1 - 5
- Cyster, M.,Smith, J.,Vogt, N.,Opletal, G.,Russo, S.,Cole, J. (2021). Simulating the fabrication of aluminium oxide tunnel junctions In: npj Quantum Information, 7, 1 - 12
- Jin, P.,Jeske, J.,Greentree, A.,Cole, J. (2021). Microwave quantum optics as a direct probe of the Overhauser field in a quantum dot circuit quantum electrodynamics device In: Physical Review B, 103, 1 - 5
- Nicolas Voss, J.,Schon, Y.,Wildermuth, M.,Dorer, D.,Cole, J.,Rotzinger, H.,Ustinov, A. (2021). Eliminating Quantum Phase Slips in Superconducting Nanowires In: ACS Nano, 15, 4108 - 4114
- Anda, A.,Cole, J. (2021). Two-dimensional spectroscopy beyond the perturbative limit: The influence of finite pulses and detection modes In: Journal of Chemical Physics, 154, 1 - 15
- Booth, J.,Klymenko, M.,Cole, J.,Russo, S. (2021). Accurate calculation of excitonic signatures in the absorption spectrum of BiSBr using semiconductor Bloch equations In: Physical Review B, 103, 1 - 7
- Li, Q.,Smith, J.,Yin, Y.,Wang, C.,Klymenko, M.,Cole, J.,Medhekar, N. (2021). Localized Wannier function based tight-binding models for two-dimensional allotropes of bismuth In: New Journal of Physics, 23, 1 - 27
- Bartolo, T.,Smith, J.,Muralidharan, B.,Müller, C.,Stace, T.,Cole, J. (2020). Aharonov-Bohm interference as a probe of Majorana fermions In: Physical Review Research, 2, 1 - 11
- Hapuarachchi, H.,Cole, J. (2020). Influence of a planar metal nanoparticle assembly on the optical response of a quantum emitter In: Physical Review Research, 2, 1 - 15
Note: Supervision projects since 2004
11 PhD Completions and 1 Masters by Research Completions6 PhD Current Supervisions
Quantum computing and information theory, spin physics, entanglement and decoherence theory, low temperature electronics
- Multidimensional Coherent Spectroscopy of Strongly Correlated Materials (administered by Swinburne University of Technology). Funded by: ARC Discovery Projects 2021 from (2021 to 2024)
- Nanoelectronics using exotic materials: novel spintronic and superconducting devices (administered by Victoria University Wellington). Funded by: Royal Society of New Zealand - Catalyst Fund from (2021 to 2024)
- Multifunctional deposition system for advanced superconducting circuits (led by The University of Sydney). Funded by: ARC LIEF via other University from (2021 to 2021)
- Cryogenic Quantum Microscope Facility (administered by University of Melbourne). Funded by: ARC Linkage Infrastructure, Equipment and Facilities (LIEF) Grant 2018 from (2018 to 2018)
- ARC Centre of Excellence in Exciton Science (Administered by The University of Melbourne). Funded by: 009-ARC Centre of Excellence via other university 2017 from (2017 to 2023)