Develops photonic-crystal-based optical biosensors and photonic-resonator-enhanced microscopy for digital-resolution, single-nanoparticle/single-quantum-dot biodetection, applied to protein, exosome, and nucleic acid diagnostics.
Gooding is one of the world's most-cited biosensor scientists (inaugural editor-in-chief of ACS Sensors) and runs a group of over thirty researchers spanning surface chemistry, electrochemistry and nanomedicine. The sensing programme that matters here is the move from ensemble to digital, single-molecule-resolved detection: nanoparticle-tethered electrochemical sensors in which single binding events are counted rather than averaged, nanopore blockade sensors for protein biomarkers such as PSA, amplification-free nucleic-acid detection, and antifouling surface chemistries that make any of this work in real biological fluid. He has a strong commercialisation record (AgaMatrix glucose sensors). Positioned against the established body of NV-ensemble quantum sensing work — DEER, nanoscale NMR and T1 relaxometry protocols operating at pT/sqrt(Hz) field sensitivity — his single-molecule-counting philosophy is the biosensing analogue of moving from a pT/sqrt(Hz) NV ensemble to single-spin detection: in both cases the sensitivity gain comes from resolving individual events rather than improving an averaged signal. He is also the obvious collaborator for anyone trying to functionalise a diamond or nanoparticle quantum sensor for a real analyte.
Reece runs UNSW's optical trapping and nanophotonics laboratory. The group combines optical tweezers with spectroscopy and microfluidics to characterise individual nanoparticles and cells: trapping and spectroscopically interrogating plasmonic core-satellite assemblies (with Gooding and Tilley), measuring single-cell mechanics, and building porous-silicon and photonic-crystal resonant structures for label-free biosensing where the analyte shifts a cavity resonance. Positioned against the established body of NV-ensemble quantum sensing work — DEER, nanoscale NMR and T1 relaxometry protocols operating at pT/sqrt(Hz) field sensitivity — optical trapping is the standard way to hold a nanoscale sensor — including a nanodiamond hosting an NV ensemble at pT/sqrt(Hz) — at a controlled position inside a cell or fluid, and levitated-nanodiamond spin-mechanics is an active field that this group's capabilities map onto almost exactly. Strong practical fit for a bio-oriented quantum sensing candidate.
Develops nanophotonic optical biosensors and spectral bioimaging techniques (metasurface/photonic-crystal based) for label-free, high-sensitivity molecular detection.