Arkady Fedorov was born in Russia and completed his undergraduate studies at the Physics Department of the St. Petersburg State University. He graduated with PhD from the Clarkson University, US in 2005. His research work was primarily on theoretical aspects of quantum information science and decoherence in solid state systems. He was then appointed a postdoctoral fellow KIT, Gemany working on a theory of superconducting quantum circuits in application to quantum computing and quantum optics phenomena. In 2007-2010 he worked in TU Delft, The Netherlands conducting experiments with superconducting flux qubits. Later on he became a research scientist in ETH Zurich to continue research in the area of superconducting quantum devices. Starting January 2013 he is a group leader at The University of Queensland. His group studies quantum phenonomena in systems consisting of superconducting artificial atoms, microwave resonators and mechanical oscillators.
Journal Article: Superconducting microwave cavities and qubits for quantum information systems
Krasnok, Alex, Dhakal, Pashupati, Fedorov, Arkady, Frigola, Pedro, Kelly, Michael and Kutsaev, Sergey (2024). Superconducting microwave cavities and qubits for quantum information systems. Applied Physics Reviews, 11 (1) ARTN 011302. doi: 10.1063/5.0155213
Journal Article: Effect of measurement backaction on quantum clock precision studied with a superconducting circuit
He, Xin, Pakkiam, Prasanna, Gangat, Adil A., Kewming, Michael J., Milburn, Gerard J. and Fedorov, Arkady (2023). Effect of measurement backaction on quantum clock precision studied with a superconducting circuit. Physical Review Applied, 20 (3) 034038. doi: 10.1103/physrevapplied.20.034038
Journal Article: Qubit-Photon Bound States: Crossover from Waveguide to Cavity Regime
Kumar, N. Pradeep, Hamann, Andrés Rosario, Navarathna, Rohit, Zanner, Maximilian, Pletyukhov, Mikhail and Fedorov, Arkady (2023). Qubit-Photon Bound States: Crossover from Waveguide to Cavity Regime. Physical Review Applied, 20 (2) 024058. doi: 10.1103/physrevapplied.20.024058
Superconducting Quantum Batteries
(2023–2027) CSIRO
Surface and Interface Engineering for Superconducting Quantum Circuits
(2023–2026) ARC Linkage Projects
Protecting superconducting qubits from quasiparticle generated by cosmic rays
(2022–2025) United States Asian Office of Aerospace Research and Development
Characterisation and optimisation of superconducting qubits
Doctor Philosophy
In situ control of photonic wavefunctions in superconducting waveguide QED
(2023) Doctor Philosophy
Measuring and suppressing superconducting qubit populations
(2023) Doctor Philosophy
Superconducting microwave cavities and qubits for quantum information systems
Krasnok, Alex, Dhakal, Pashupati, Fedorov, Arkady, Frigola, Pedro, Kelly, Michael and Kutsaev, Sergey (2024). Superconducting microwave cavities and qubits for quantum information systems. Applied Physics Reviews, 11 (1) ARTN 011302. doi: 10.1063/5.0155213
Effect of measurement backaction on quantum clock precision studied with a superconducting circuit
He, Xin, Pakkiam, Prasanna, Gangat, Adil A., Kewming, Michael J., Milburn, Gerard J. and Fedorov, Arkady (2023). Effect of measurement backaction on quantum clock precision studied with a superconducting circuit. Physical Review Applied, 20 (3) 034038. doi: 10.1103/physrevapplied.20.034038
Qubit-Photon Bound States: Crossover from Waveguide to Cavity Regime
Kumar, N. Pradeep, Hamann, Andrés Rosario, Navarathna, Rohit, Zanner, Maximilian, Pletyukhov, Mikhail and Fedorov, Arkady (2023). Qubit-Photon Bound States: Crossover from Waveguide to Cavity Regime. Physical Review Applied, 20 (2) 024058. doi: 10.1103/physrevapplied.20.024058
Testing spontaneous wavefunction collapse with quantum electromechanics
Tobar, Germain, Forstner, Stefan, Fedorov, Arkady and Bowen, Warwick P. (2023). Testing spontaneous wavefunction collapse with quantum electromechanics. Quantum Science and Technology, 8 (4) 045003, 045003. doi: 10.1088/2058-9565/ace2e5
Near-field localization of the boson peak on tantalum films for superconducting quantum devices
Guo, Xiao, Degnan, Zachary, Steele, Julian A., Solano, Eduardo, Donose, Bogdan C., Bertling, Karl, Fedorov, Arkady, Rakić, Aleksandar D. and Jacobson, Peter (2023). Near-field localization of the boson peak on tantalum films for superconducting quantum devices. The Journal of Physical Chemistry Letters, 14 (20), 4892-4900. doi: 10.1021/acs.jpclett.3c00850
Terahertz nanospectroscopy of plasmon polaritons for the evaluation of doping in quantum devices
Guo, Xiao, He, Xin, Degnan, Zachary, Chiu, Chun-Ching, Donose, Bogdan C., Bertling, Karl, Fedorov, Arkady, Rakić, Aleksandar D. and Jacobson, Peter (2023). Terahertz nanospectroscopy of plasmon polaritons for the evaluation of doping in quantum devices. Nanophotonics, 12 (10), 1865-1875. doi: 10.1515/nanoph-2023-0064
Passive superconducting circulator on a chip
Navarathna, Rohit, Le, Dat Thanh, Rosario Hamann, Andrés, Nguyen, Hien Duy, Stace, Thomas M. and Fedorov, Arkady (2023). Passive superconducting circulator on a chip. Physical Review Letters, 130 (3) 037001, 037001. doi: 10.1103/physrevlett.130.037001
Ternary metal oxide substrates for superconducting circuits
Degnan, Zach, He, Xin, Frieiro, Alejandro Gomez, Sachkou, Yauhen, Fedorov, Arkady and Jacobson, Peter (2022). Ternary metal oxide substrates for superconducting circuits. Materials for Quantum Technology, 2 (2) 025004. doi: 10.1088/2633-4356/ac70a2
Operating a passive on-chip superconducting circulator: Device control and quasiparticle effects
Le, Dat Thanh, Müller, Clemens, Navarathna, Rohit, Fedorov, Arkady and Stace, T. M. (2021). Operating a passive on-chip superconducting circulator: Device control and quasiparticle effects. Physical Review Research, 3 (4) 043211. doi: 10.1103/physrevresearch.3.043211
Approximations in transmon simulation
Jones, Tyler, Steven, Kaiah, Poncini, Xavier, Rose, Matthew and Fedorov, Arkady (2021). Approximations in transmon simulation. Physical Review Applied, 16 (5) 054039. doi: 10.1103/physrevapplied.16.054039
Neural networks for on-the-fly single-shot state classification
Navarathna, Rohit, Jones, Tyler, Moghaddam, Tina, Kulikov, Anatoly, Beriwal, Rohit, Jerger, Markus, Pakkiam, Prasanna and Fedorov, Arkady (2021). Neural networks for on-the-fly single-shot state classification. Applied Physics Letters, 119 (11) 114003, 114003. doi: 10.1063/5.0065011
Near-field terahertz nanoscopy of coplanar microwave resonators
Guo, Xiao, He, Xin, Degnan, Zach, Donose, Bogdan C., Bertling, Karl, Fedorov, Arkady, Rakić, Aleksandar D. and Jacobson, Peter (2021). Near-field terahertz nanoscopy of coplanar microwave resonators. Applied Physics Letters, 119 (9) 091101, 1-6. doi: 10.1063/5.0061078
Z2 lattice gauge theories and Kitaev's toric code: A scheme for analog quantum simulation
Homeier, Lukas, Schweizer, Christian, Aidelsburger, Monika, Fedorov, Arkady and Grusdt, Fabian (2021). Z2 lattice gauge theories and Kitaev's toric code: A scheme for analog quantum simulation. Physical Review B, 104 (8) 085138. doi: 10.1103/PhysRevB.104.085138
Measuring effective temperatures of qubits using correlations
Kulikov, Anatoly, Navarathna, Rohit and Fedorov, Arkady (2020). Measuring effective temperatures of qubits using correlations. Physical Review Letters, 124 (24) 240501, 240501. doi: 10.1103/physrevlett.124.240501
Probabilistic motional averaging
Karpov, Denys S., Monarkha, Vladimir Y., Szombati, Daniel, Frieiro, Alejandro G., Omelyanchouk, Aleksander N., Il’ichev, Evgeni, Fedorov, Arkady and Shevchenko, Sergey N. (2020). Probabilistic motional averaging. European Physical Journal B, 93 (3) 49. doi: 10.1140/epjb/e2019-100514-8
Quantum rifling: protecting a qubit from measurement back action
Szombati, Daniel, Gomez Frieiro, Alejandro, Müller, Clemens, Jones, Tyler, Jerger, Markus and Fedorov, Arkady (2020). Quantum rifling: protecting a qubit from measurement back action. Physical Review Letters, 124 (7) 070401, 070401. doi: 10.1103/physrevlett.124.070401
In situ characterization of qubit control lines: a qubit as a vector network analyzer
Jerger, Markus, Kulikov, Anatoly, Vasselin, Zénon and Fedorov, Arkady (2019). In situ characterization of qubit control lines: a qubit as a vector network analyzer. Physical Review Letters, 123 (15) 150501, 150501. doi: 10.1103/PhysRevLett.123.150501
Nonreciprocity realized with quantum nonlinearity
Rosario Hamann, Andrés, Müller, Clemens, Jerger, Markus, Zanner, Maximilian, Combes, Joshua, Pletyukhov, Mikhail, Weides, Martin, Stace, Thomas M. and Fedorov, Arkady (2018). Nonreciprocity realized with quantum nonlinearity. Physical Review Letters, 121 (12) 123601, 123601. doi: 10.1103/PhysRevLett.121.123601
Realization of a quantum random generator certified with the Kochen-Specker theorem
Kulikov, Anatoly, Jerger, Markus, Potočnik, Anton, Wallraff, Andreas and Fedorov, Arkady (2017). Realization of a quantum random generator certified with the Kochen-Specker theorem. Physical Review Letters, 119 (24) 240501, 240501. doi: 10.1103/PhysRevLett.119.240501
Nonreciprocal atomic scattering: A saturable, quantum Yagi-Uda antenna
Müller, Clemens, Combes, Joshua, Hamann, Andrés Rosario, Fedorov, Arkady and Stace, Thomas M. (2017). Nonreciprocal atomic scattering: A saturable, quantum Yagi-Uda antenna. Physical Review A, 96 (5) 053817, 1-10. doi: 10.1103/PhysRevA.96.053817
3D microwave cavity with magnetic flux control and enhanced quality factor
Reshitnyk, Yarema, Jerger, Markus and Fedorov, Arkady (2016). 3D microwave cavity with magnetic flux control and enhanced quality factor. EPJ Quantum Technology, 3 (1) 13. doi: 10.1140/epjqt/s40507-016-0050-8
Contextuality without nonlocality in a superconducting quantum system
Jerger, Markus, Reshitnyk, Yarema, Oppliger, Markus, Potocnik, Anton, Mondal, Mintu, Wallraff, Andreas, Goodenough, Kenneth, Wehner, Stephanie, Juliusson, Kristinn, Langford, Nathan K. and Fedorov, Arkady (2016). Contextuality without nonlocality in a superconducting quantum system. Nature Communications, 7 (1) 12930, 12930. doi: 10.1038/ncomms12930
Jerger, Markus, Macha, Pascal, Hamann, Andres Rosario, Reshitnyk, Yarema, Juliusson, Kristinn and Fedorov, Arkady (2016). Realization of a binary-outcome projection measurement of a three-Level superconducting quantum system. Physical Review Applied, 6 (1) 014014. doi: 10.1103/PhysRevApplied.6.014014
Quartz-superconductor quantum electromechanical system
Woolley, M. J., Emzir, M. F., Milburn, G. J., Jerger, M., Goryachev, M., Tobar, M. E. and Fedorov, A. (2016). Quartz-superconductor quantum electromechanical system. Physical Review B, 93 (22) 224518. doi: 10.1103/PhysRevB.93.224518
Higher-order nonlinear effects in a Josephson parametric amplifier
Kochetov, Bogdan and Fedorov, Arkady (2015). Higher-order nonlinear effects in a Josephson parametric amplifier. Physical Review B - Condensed Matter and Materials Physics, 92 (22) 220102. doi: 10.1103/PhysRevB.92.224304
Input-output theory for waveguide QED with an ensemble of inhomogeneous atoms
Lalumiere, K., Sanders, B. C., Van Loo, A. F., Fedorov, A., Wallraff, A. and Blais, A. (2013). Input-output theory for waveguide QED with an ensemble of inhomogeneous atoms. Physical Review A - Atomic, Molecular, and Optical Physics, 88 (4) 043806. doi: 10.1103/PhysRevA.88.043806
Exploring the effect of noise on the Berry phase
Berger, S., Pechal, M., Abdumalikov, A. A., Eichler, C., Steffen, L., Fedorov, A., Wallraff, A. and Filipp, S. (2013). Exploring the effect of noise on the Berry phase. Physical Review A - Atomic, Molecular, and Optical Physics, 87 (6) 060303, 060303-1-060303-5. doi: 10.1103/PhysRevA.87.060303
Deterministic quantum teleportation with feed-forward in a solid state system
Steffen, L., Salathe, Y., Oppliger, M., Kurpiers, P., Baur, M., Lang, C., Eichler, C., Puebla-Hellmann, G., Fedorov, A. and Wallraff, A. (2013). Deterministic quantum teleportation with feed-forward in a solid state system. Nature, 500 (7462), 319-322. doi: 10.1038/nature12422
Photon-mediated interactions between distant artificial atoms
Van Loo, Arjan F., Fedorov, Arkady, Lalumiere, Kevin, Sanders, Barry C., Blais, Alexandre and Wallraff, Andreas (2013). Photon-mediated interactions between distant artificial atoms. Science, 342 (6165), 1494-1496. doi: 10.1126/science.1244324
Geometric phases in superconducting qubits beyond the two-level approximation
Berger, S., Pechal, M., Pugnetti, S., Abdumalikov, A. A., Jr., Steffen, L., Fedorov, A., Wallraff, A. and Filipp, S. (2012). Geometric phases in superconducting qubits beyond the two-level approximation. Physical Review B, 85 (22) doi: 10.1103/PhysRevB.85.220502
Quantum-control approach to realizing a Toffoli gate in circuit QED
Stojanovic, Vladimir M., Fedorov, A., Wallraff, A. and Bruder, C. (2012). Quantum-control approach to realizing a Toffoli gate in circuit QED. Physical Review B, 85 (5) 054504 doi: 10.1103/PhysRevB.85.054504
Baur, M., Fedorov, A., Steffen, L., Filipp, S., da Silva, M. P. and Wallraff, A. (2012). Benchmarking a quantum teleportation protocol in superconducting circuits using tomography and an entanglement witness. Physical Review Letters, 108 (4) doi: 10.1103/PhysRevLett.108.040502
Implementation of a Toffoli gate with superconducting circuits
Fedorov, A., Steffen, L., Baur, M., da Silva, M. P. and Wallraff, A. (2012). Implementation of a Toffoli gate with superconducting circuits. Nature, 481 (7380), 170-172. doi: 10.1038/nature10713
Tuned transition from quantum to classical for macroscopic quantum states
Fedorov, A., Macha, P., Feofanov, A. K., Harmans, C. J. P. M. and Mooij, J. E. (2011). Tuned transition from quantum to classical for macroscopic quantum states. Physical Review Letters, 106 (17). doi: 10.1103/PhysRevLett.106.170404
Strong coupling of a quantum oscillator to a flux qubit at its symmetry point
Fedorov, A., Feofanov, A. K., Macha, P., Forn-Diaz, P., Harmans, C. J. P. M. and Mooij, J. E. (2010). Strong coupling of a quantum oscillator to a flux qubit at its symmetry point. Physical Review Letters, 105 (6) doi: 10.1103/PhysRevLett.105.060503
Tuning the gap of a superconducting flux qubit
Paauw, F. G., Fedorov, A., Harmans, C. J. P. M. and Mooij, J. E. (2009). Tuning the gap of a superconducting flux qubit. Physical Review Letters, 102 (9) doi: 10.1103/PhysRevLett.102.090501
Dissipation in circuit quantum electrodynamics: Lasing and cooling of a low-frequency oscillator
Hauss, Julian, Fedorov, Arkady, Andre, Stephan, Brosco, Valentina, Hutter, Carsten, Kothari, Robin, Yeshwanth, Sunil, Shnirman, Alexander and Schoen, Gerd (2008). Dissipation in circuit quantum electrodynamics: Lasing and cooling of a low-frequency oscillator. New Journal of Physics, 10 (9), 095018. doi: 10.1088/1367-2630/10/9/095018
Sisyphus cooling and amplification by a superconducting qubit
Grajcar, M., Van Der Ploeg, S. H. W., Izmalkov, A., IL'Ichev, E., Meyer, H. -G., Fedorov, A., Shnirman, A. and Schoen, Gerd (2008). Sisyphus cooling and amplification by a superconducting qubit. Nature Physics, 4 (8), 612-616. doi: 10.1038/nphys1019
Single-qubit lasing and cooling at the rabi frequency
Hauss, Julian, Fedorov, Arkady, Hutter, Carsten, Shnirman, Alexander and Schoen, Gerd (2008). Single-qubit lasing and cooling at the rabi frequency. Physical Review Letters, 100 (3) doi: 10.1103/PhysRevLett.100.037003
Reading out the state of a flux qubit by Josephson transmission line solitons
Fedorov, Arkady, Shnirman, Alexander and Schoen, Gerd (2007). Reading out the state of a flux qubit by Josephson transmission line solitons. Physical Review B, 75 (22) doi: 10.1103/PhysRevB.75.224504
Collective decoherence of nuclear spin clusters
Fedorov, A and Fedichkin, L (2006). Collective decoherence of nuclear spin clusters. Journal of Physics-Condensed Matter, 18 (12), 3217-3228. doi: 10.1088/0953-8984/18/12/005
Spin-photovoltaic effect in quantum wires due to intersubband transitions
Fedorov, A, Pershin, YV and Piermarocchi, C (2005). Spin-photovoltaic effect in quantum wires due to intersubband transitions. Physical Review B, 72 (24) 245327 doi: 10.1103/PhysRevB.72.245327
Additivity of decoherence measures for multiqubit quantum systems
Fedichkin, L, Fedorov, A and Privman, V (2004). Additivity of decoherence measures for multiqubit quantum systems. Physics Letters a, 328 (2-3), 87-93. doi: 10.1016/j.physleta.2004.06.021
Evaluation of decoherence for quantum control and computing
Fedorov, Arkady, Fedichkin, Leonid and Privman, Vladimir (2004). Evaluation of decoherence for quantum control and computing. Journal of Computational and Theoretical Nanoscience, 1 (2), 132-143. doi: 10.1166/jctn.2004.011
Error rate of a charge qubit coupled to an acoustic phonon reservoir
Fedichkin, L and Fedorov, A (2004). Error rate of a charge qubit coupled to an acoustic phonon reservoir. Physical Review a, 69 (3) 032311 doi: 10.1103/PhysRevA.69.032311
Terahertz nanoscopy: a non-destructive characterization tool for nanomaterials and nanostructures
Guo, Xiao, Bertling, Karl, Donose, Bogdan C., He, Xin, Degnan, Zach, Solemanifar, Armin, Zhang, Xueqin, Laycock, Bronwyn, Virdis, Bernardino, Fedorov, Arkady, Jacobson, Peter and Rakić, Aleksandar D. (2022). Terahertz nanoscopy: a non-destructive characterization tool for nanomaterials and nanostructures. The 2022 Conference on Optoelectronic and Microelectronic Materials and Devices, Adelaide, SA Australia, 11-16 December 2022.
Advances and challenges in THz scattering SNOM
Guo, Xiao, Donose, Bogdan, Bertling, Karl, He, Xin, Degnan, Zach, Solemanifar, Armin, Laycock, Bronwyn, Fedorov, Arkady, Jacobson, Peter and Rakic, Aleksandar (2021). Advances and challenges in THz scattering SNOM. 8th Australian THz Workshop, Sydney, NSW Australia, 3 December 2021.
Near-field terahertz nanoscopy of coplanar microwave resonators
Jacobson, Peter, Guo, Xiao, He, Xin, Degnan, Zach, Donose, Bogdan, Bertling, Karl, Fedorov, Arkady and Rakic, Aleksandar (2021). Near-field terahertz nanoscopy of coplanar microwave resonators. Australian Institute of Physics Summer Meeting, Brisbane, QLD Australia, 6th-9th December 2021.
Nonreciprocity with a nonlinear superconducting circuit
Hamann, Andrés Rosario, Müller, Clemens, Jerger, Markus, Combes, Joshua, Stace, Thomas M., Fedorov, Arkady, Zanner, Maximilian, Weides, Martin and Pletyukhov, Mikhail (2019). Nonreciprocity with a nonlinear superconducting circuit. Quantum Information and Measurement (QIM) V: Quantum Technologies, Rome, Italy, 4-6 April 2019. Washington, D.C.: OSA. doi: 10.1364/qim.2019.f5a.58
The Lagrangian approach to a Josephson traveling-wave parametric amplifier
Kochetov, Bogdan A. and Fedorov, Arkady (2016). The Lagrangian approach to a Josephson traveling-wave parametric amplifier. 8th International Conference on Ultrawideband and Ultrashort Impulse Signals, UWBUSIS 2016, Odessa, Ukraine, 5 - 11 September 2016. Piscataway, NJ, United States: Institute of Electrical and Electronics Engineers. doi: 10.1109/UWBUSIS.2016.7724164
Decoherence and Relaxation in Driven Circuit QED Systems
Andre, Stephan, Brosco, Valentina, Fedorov, Arkady, Schoen, Gerd and Shnirman, Alexander (2008). Decoherence and Relaxation in Driven Circuit QED Systems. 2nd International Workshop on Solid-State Quantum Computing/Mini-School on Quantum Information Science, Taipei Taiwan, Jun 23-27, 2008. AMER INST PHYSICS. doi: 10.1063/1.3037135
Spin-Photovoltaic Effect in Quantum Wires
Fedorov, A., Pershin, Yu. V. and Piermarocchi, C. (2008). Spin-Photovoltaic Effect in Quantum Wires. 4th International Symposium on Mesoscopic Superconductivity and Spintronics, Atsugi Japan, Feb 27-Mar 02, 2006. WORLD SCIENTIFIC PUBL CO PTE LTD. doi: 10.1142/9789812814623_0051
Design of a ballistic fluxon qubit readout
Herr, Anna, Fedorov, Arkady, Shnirman, Alexander, Il'ichev, Evgeny and Schon, Gerd (2007). Design of a ballistic fluxon qubit readout. 11th International Superconductive Electronics Conference, Washington Dc, Jun, 2007. doi: 10.1088/0953-2048/20/11/S29
Fedichkin, L and Fedorov, A (2005). Study of temperature dependence of electron-phonon relaxation and dephasing in semiconductor double-dot nanostructures. IEEE Nanotechnology Council Quantum Device Technology Workshop, Potsdam Ny, May 17-21, 2004. doi: 10.1109/TNANO.2004.840156
Decoherence of localized electrons in semiconductors due to acoustic phonons
Fedichkin, L, Fedorov, A and Yanchenko, M (2003). Decoherence of localized electrons in semiconductors due to acoustic phonons. Conference on Quantum Information and Computation, Orlando Fl, Apr 21-22, 2003. doi: 10.1117/12.487993
Fedichkin, L, Fedorov, A and Privman, V (2003). Measures of Decoherence. Conference on Quantum Information and Computation, Orlando Fl, Apr 21-22, 2003. doi: 10.1117/12.486792
Individual measurement outcomes of a KCBS test for hidden variables in a superconducting qutrit
Jerger, Markus and Fedorov, Arkady (2016). Individual measurement outcomes of a KCBS test for hidden variables in a superconducting qutrit. The University of Queensland. (Collection) doi: 10.14264/uql.2016.207
Superconducting Quantum Batteries
(2023–2027) CSIRO
Surface and Interface Engineering for Superconducting Quantum Circuits
(2023–2026) ARC Linkage Projects
Protecting superconducting qubits from quasiparticle generated by cosmic rays
(2022–2025) United States Asian Office of Aerospace Research and Development
Clean and Tunable Phase Slip Qubit
(2021–2023) United States Asian Office of Aerospace Research and Development
(2020–2024) Foundational Questions Institute
Experiments supporting a fully certified quantum random number generator
(2019–2021) Lockheed Martin Corporation (USA)
ARC Centre of Excellence for Engineered Quantum Systems (EQuS2)
(2018–2025) ARC Centres of Excellence
(2018–2019) University of Western Australia
Imaging in the nano-scale age: terahertz and millimetre wave microanalysis
(2018) UQ Major Equipment and Infrastructure
Non-reciprocal quantum devices on a chip
(2017) UQ Foundation Research Excellence Awards - DVC(R) Funding
Distributed quantum networks with cascaded superconducting circuits
(2015–2019) ARC Future Fellowships
Quantum networks based on superconducting circuits and dissipative channels
(2015–2017) ARC Discovery Projects
Advanced Superfluid Physics Facility
(2015–2016) UQ Major Equipment and Infrastructure
Microwave photon engineering with superconducting qubit chains
(2014–2015) Go8 Australia - Germany Joint Research Co-operation Scheme
Design and characterization of coherent three-dimensional quantum circuits
(2014) UQ Early Career Researcher
Facility for fabrication and characterisation of micro/nano-optoelectronic devices
(2014) UQ Major Equipment and Infrastructure
ARC Centre of Excellence for Engineered Quantum Systems (EQuS)
(2011–2017) ARC Centres of Excellence
Characterisation and optimisation of superconducting qubits
Doctor Philosophy — Principal Advisor
The data-driven model identification and model predictive control techniques for superconducting qubits
Doctor Philosophy — Principal Advisor
Other advisors:
Fanrication and measurement of coherent superconducting qubits
Doctor Philosophy — Principal Advisor
Other advisors:
Superconducting circuits as quantum clocks
Doctor Philosophy — Principal Advisor
Other advisors:
Increasing coherence of superconducting qubits
Doctor Philosophy — Principal Advisor
Other advisors:
Surface and Interface Engineering for Superconducting Devices
Doctor Philosophy — Associate Advisor
Other advisors:
Engineering phonons to improve superconducting quantum computing
Doctor Philosophy — Associate Advisor
Other advisors:
In situ control of photonic wavefunctions in superconducting waveguide QED
(2023) Doctor Philosophy — Principal Advisor
Other advisors:
Measuring and suppressing superconducting qubit populations
(2023) Doctor Philosophy — Principal Advisor
Protecting superconducting quantum circuits from measurement back-action and ionizing radiation
(2022) Doctor Philosophy — Principal Advisor
Other advisors:
In situ quantum control over superconducting qubits
(2020) Doctor Philosophy — Principal Advisor
Rectangular waveguide QED with superconducting qubits
(2019) Doctor Philosophy — Principal Advisor
Engineered quantum systems for quantum computation with superconducting circuits
(2022) Doctor Philosophy — Associate Advisor
Other advisors:
Note for students: The possible research projects listed on this page may not be comprehensive or up to date. Always feel free to contact the staff for more information, and also with your own research ideas.