Description: Scattering-type near-field optical microscopy at THz frequencies for nanoscale material characterisation.
Aurรจle Adam develops THz near-field imaging and spectroscopy. Research: (1) apertureless scattering-type near-field optical microscopy (s-SNOM) at THz frequencies for nanometre spatial resolution imaging of material properties; (2) THz time-domain spectroscopy of quantum materials and condensed matter systems; (3) antenna-coupled detectors and sources for THz near-field imaging. Relevant to quantum material characterisation at the nanoscale.
Kuhlmey works on structured electromagnetic materials across an unusually wide frequency range: microstructured optical fibres, metamaterials, non-reciprocal and time-varying media, and โ the newest and most sensing-relevant thread โ quantum terahertz photonics, in collaboration with ENS Paris and CSIRO. The THz programme is explicitly aimed at single-photon/single-electron coupling in the THz band, which if it works would allow quantum devices to operate at a few kelvin rather than millikelvin. The group runs a THz time-domain spectroscopy lab with cryogenic capability. Positioned against the established body of NV-ensemble quantum sensing work โ DEER, nanoscale NMR and T1 relaxometry protocols operating at pT/sqrt(Hz) field sensitivity โ the THz band is the one part of the spectrum where neither superconducting circuits nor NV ensembles currently offer quantum-limited detection, so this is a genuine gap-filling programme rather than a variation on existing pT/sqrt(Hz) approaches.