Edel's group develops nanopore- and nanogap-based single-molecule sensing platforms, combining nanofluidics, plasmonics and electrical/optical readout for ultrasensitive detection and sequencing of biomolecules.
Eggleton directs the Institute of Photonics and Optical Science and runs one of the world's leading groups on stimulated Brillouin scattering in integrated photonic circuits β the coherent interaction of light with GHz acoustic phonons in a chalcogenide or silicon waveguide. The consequences are a chip-scale microwave photonic toolbox (ultra-narrowband filters, true time delay, RF spectral analysis), photon-phonon memory, and, through the Jericho Smart Sensing Laboratory, translation into deployed sensing platforms. 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 Brillouin optomechanics is a distinct route to the same goal β reading a weak signal out of a high-Q, low-loss resonator at the quantum noise floor β and the group's phonon-photon coupling is strong enough that quantum optomechanical operation is now within reach. Very large, very well-resourced group with extensive industry and defence funding; a candidate would be one of many.
Develops biophotonics and optical instrumentation for live-cell and cancer imaging, including multiphoton microscopy, image informatics, and quantitative image analysis tools; affiliated with the Morgridge Institute for Research.
The Endres group assembles programmable arrays of individually trapped neutral atoms (Rydberg and alkaline-earth) to advance quantum metrology, entanglement-enhanced optical clocks, and many-body simulation, demonstrating record atom-array optical-clock stability and quantum-enhanced sensing protocols. For context, this complements the established paradigm of NV-diamond ensemble magnetometry (Hahn-echo/DEER, nanoscale NMR, T1 relaxometry) operating near pT/βHz sensitivity.
Research focuses on quantum dynamics and excited-state reactivity in biological and synthetic light-harvesting systems. Discovered long-lived quantum coherence in photosynthetic light-harvesting complexes (FMO, 2007). Develops 2D electronic spectroscopy techniques to probe excitonic transport, open quantum systems, and photochemical reaction dynamics on femtosecond timescales. Director NSF QuBBE; co-director Berggren Center for Quantum Biology and Medicine.
PREFERRED. Englund's Quantum Photonics Laboratory builds solid-state quantum technologies spanning diamond NV-center ensembles, integrated photonic circuits, and single-photon detectors, including a CMOS-integrated NV-ensemble quantum sensor for vector magnetometry and 4-pi steradian field sensing, and cavity-QED schemes for nuclear-spin readout aimed at nanoscale/inertial sensing. This continues the trajectory of NV ensemble quantum sensing (DEER, chip-scale NMR, T1 relaxometry) toward pT/sqrt(Hz)-class, chip-integrated magnetometers, alongside quantum networking and photonic quantum computing work.
Studies galaxy formation and evolution, dwarf galaxies, stellar populations, and spectroscopic properties of distant-universe galaxies.
Primary focus: immune engineering for vaccines and cancer immunotherapy. Quantum sensing relevance: co-authored 2025 fluorescent-protein spin qubit paper (Physics World Top-10) with Maurer and Awschalom, contributing protein engineering expertise to develop biological alternatives to NV centers. Collaborates on quantum biosensors for real-time monitoring of immune cell activity (Chan Zuckerberg Biohub). Primarily a collaboration gateway for NV biosensing rather than standalone quantum sensing PI.
PREFERRED. Evans leads work on frequency-dependent squeezed-light injection and low-thermal-noise optics that has pushed Advanced LIGO below the standard quantum limit across its full detection band, and he leads the US design effort for the next-generation Cosmic Explorer gravitational-wave observatory. This is squarely quantum-enhanced sensing at a fundamental-physics facility scale rather than a device-fabrication program.
Faist is the inventor of the quantum cascade laser (QCL, 1994 at Bell Labs) and leads the Quantum Optoelectronics Group at ETH. Research directions: (1) QCL frequency combs β ring QCLs demonstrate dissipative Kerr solitons in the THz (Science Advances 2023), key for broadband integrated mid-IR spectrometers; (2) Dual-comb spectroscopy β two co-integrated ring QCLs for ultrafast molecular fingerprinting; (3) Quantum cascade detectors β strain-compensated InGaAs/InAlAs QCDs for short-wave mid-IR (<4 Β΅m) sensing; (4) THz strong-coupling β ultrastrongly coupled 2DEG in cavities for quantum photonics; (5) Astrophysical heterodyne receivers β double-metal QCL Josephson mixers. Spin-off: IRsweep (mid-IR dual-comb systems) and Alpes Lasers (QCL commercialisation). FIRST Center head at ETH.