STAFF PROFILE
Dr Brett Johnson
Position:
Research Fellow
College / Portfolio:
STEM College
School / Department:
STEM|School of Science
Phone:
+61399255363
Email:
brett.johnson2@rmit.edu.au
Campus:
City Campus
Contact me about:
Research supervision
- Alyabyeva, N.,Ding, J.,Sauty, M.,Woerle, J.,Jousseaume, Y.,Ferro, G.,McCallum, J.,Peretti, J.,Johnson, B.,Rowe, A. (2023). Nanoscale Mapping of Sub-Gap Electroluminescence from Step-Bunched, Oxidized 4H-SiC Surfaces In: Physica Status Solidi (B) Basic Research, 260, 1 - 6
- Wang, S.,Chapman, R.,Johnson, B.,Krasnokutska, I.,Tambasco, J.,Messalea, K.,Peruzzo, A.,Bullock, J. (2023). Integration of Black Phosphorus Photoconductors with Lithium Niobate on Insulator Photonics In: Advanced Optical Materials, 11, 1 - 6
- Berkman, I.,Lyasota, A.,de Boo, G.,Bartholomew, J.,Johnson, B., et al, . (2023). Observing Er3+ Sites in Si with an in Situ Single-Photon Detector In: Physical Review Applied, 19, 1 - 11
- Johnson, B.,Stuiber, M.,Creedon, D.,van Beveren, L.,Rubanov, S.,Cole, J.,Duty, T. L., et al, . (2023). Silicon-Aluminum Phase-Transformation-Induced Superconducting Rings In: Nano Letters, 23, 17 - 24
- Wang, S.,Ashokan, A.,Balendhran, S.,Yan, W.,Johnson, B.,Peruzzo, A.,Crozier, K.,Mulvaney, P.,Bullock, J. (2023). Room Temperature Bias-Selectable, Dual-Band Infrared Detectors Based on Lead Sulfide Colloidal Quantum Dots and Black Phosphorus In: ACS Nano, 17, 11771 - 11782
- Voisin, B.,Salfi, J.,St Médar, D.,Johnson, B.,McCallum, J.,Simmons, M.,Rogge, S. (2023). A solid-state quantum microscope for wavefunction control of an atom-based quantum dot device in silicon In: Nature Electronics, 6, 409 - 416
- Collins, N.,Jakob, A.,Robson, S.,Lim, S.,Räcke, P.,Johnson, B.,Liu, B.,Lu, Y.,Spemann, D.,McCallum, J.,Jamieson, D. (2023). Graphene-Enhanced Single Ion Detectors for Deterministic Near-Surface Dopant Implantation in Diamond In: Advanced Functional Materials, 33, 1 - 10
- Voisin, B.,Johnson, B.,Hollenberg, L.,Rogge, S., et al, . (2022). Valley population of donor states in highly strained silicon In: Materials for Quantum Technology, 2, 1 - 10
- S, S.,Abrahams, G.,Johnson, B.,Healey, A.,Robertson, I.,Simpson, D.,Stacey, A.,Onoda, S.,Ohshima, T.,Kho, T.,Michel, J.,Bullock, J.,Hollenberg, L.,Tetienne, J. (2022). Imaging Current Paths in Silicon Photovoltaic Devices with a Quantum Diamond Microscope In: Physical Review Applied, 18, 1 - 14
- Yang, Y.,Vallabhapurapu, H.,Sewani, V.,Isarov, M.,Firgau, H.,Adambukulam, C.,Johnson, B.,Pla, J.,Laucht, A. (2022). Observing hyperfine interactions of NV-centers in diamond in an advanced quantum teaching lab In: American Journal of Physics, 90, 550 - 560
2 PhD Current Supervisions
- Quantum microscopy meets photovoltaics: new tools for solar cell research. Funded by: ARC Discovery Projects commencing in 2022 from (2022 to 2025)
- Superconducting silicon nanodevice (Administered by University of Melbourne). Funded by: ARC Discovery Project via Other University from (2021 to 2024)