Description: Pulsed excitation with TCSPC or streak camera detection for carrier lifetime, exciton dynamics, and defect characterization in photonic materials and quantum dots.
Parkinson's group uses ultrafast optical spectroscopy to study carrier dynamics in photonic materials with quantum device applications. Research directions: (1) Time-resolved photoluminescence β TRPL with single-photon counting to map exciton lifetimes, diffusion, and defect trapping in GaN, perovskite, and 2D semiconductor quantum wells; (2) Optical single-particle spectroscopy β isolating single nanowires or nanocrystals for defect-free measurements of intrinsic optical properties; (3) Photon-number statistics β Hanbury BrownβTwiss measurements of single-photon purity from quantum dots and localized excitons; (4) Semiconductor quantum sensing interfaces β studying how carrier dynamics affect the fidelity of semiconductor-based quantum sensors and emitters.
Smith runs Melbourne's time-resolved fluorescence facility and specialises in the information channels most people throw away: fluorescence lifetime, anisotropy decay and its orientational content, and single-molecule photophysics, applied to organic semiconductors, energy-transfer systems and biological samples. The group builds its own confocal microspectroscopy instrumentation for time-resolved anisotropy imaging and single-molecule detection. Positioned against the established body of NV-ensemble quantum sensing work β DEER, nanoscale NMR and T1 relaxometry protocols operating at pT/sqrt(Hz) field sensitivity β lifetime- and orientation-resolved fluorescence is the principal orthogonal contrast mechanism to spin-based sensing, and his instrumentation is the natural correlative partner for NV-ensemble DEER/relaxometry experiments at pT/sqrt(Hz) that need an independent optical readout of the same specimen. Preferred attribute present: orientation- and lifetime-resolved methods.
Zheltikov integrates NV-diamond magnetometry into photonic-crystal fibers for high-resolution, fiber-delivered magnetic-field imaging and endoscopy, alongside ultrafast biophotonics (multiphoton deep-tissue imaging, SWIR probes) and quantum-light molecular spectroscopy. In the broader landscape of NV-centre ensemble quantum sensing (DEER, nano-NMR, T1 relaxometry) operating near pT/sqrt(Hz) sensitivity, this work extends NV ensemble sensing into fiberized, in-vivo-compatible geometries.