PIs - interested: False

Department(s)/lab(s): Physics – Laboratory for Solid State Physics (ETH) / PSI / EPFL | Quantum Technologies Group (Aeppli, ETH/PSI/EPFL) @ ETH Zurich
Summary:

Aeppli leads the Quantum Technologies Group spanning ETH Zurich, EPFL, and PSI. Research directions: (1) Quantum materials imaging β€” using SLS synchrotron X-rays (including SwissFEL ultrafast pulses) and neutrons at SINQ to image quantum phase transitions, skyrmions, and correlated phases; non-destructive imaging of device structures; (2) Rare-earth quantum magnets and qubits β€” LiHoF4 as a model quantum system; Er, Pr, and Nd spin qubits in crystals for quantum information and sensing; (3) Semiconductor quantum devices β€” silicon and germanium nanostructures probed by synchrotron nanoscale X-ray imaging; (4) Van der Waals materials and CDW memory devices. Strong interface with PSI large-scale facilities as unique quantum sensing tools for materials.

Department(s)/lab(s): Materials Science and Engineering | Anikeeva Lab (Bioelectronics Group) @ MIT
Summary:

PREFERRED. Anikeeva's Bioelectronics Group engineers minimally invasive, multifunctional fiber-based neural probes (combining optical, electrical, and microfluidic channels) and magnetic nanoparticle transducers that enable wireless, gene- and wire-free magnetothermal, magnetomechanical, and chemomagnetic neuromodulation, with applications spanning deep-brain stimulation and gut-brain circuit interrogation.

Department(s)/lab(s): Physics – Institute for Quantum Electronics | Quantum Control for Fundamental Physics Group (Craik Group) @ ETH Zurich
Summary:

Craik leads the RAVIOLIS project (SNSF Starting Grant, started July 2025) measuring atomic parity violation in barium ions at <0.1% precision. Her entanglement protocol uses multi-ion entangled states with photonic integrated waveguide addressing to common-mode-reject parity-conserving systematics. Previous work: precision measurement of Ba+ dipole transition probabilities below 1% uncertainty; first laser-guided individual addressing of Ba+ qubits with <10^-4 intensity crosstalk; isotope-shift spectroscopy in Ca+ for fifth-force searches. She is actively recruiting for postdocs and PhD students for the new Ba+ ion trap experiment.

Department(s)/lab(s): Biological Engineering | Bathe Lab (Laboratory for Nucleic Acid Nanotechnology) @ MIT
Summary:

PREFERRED. Bathe's lab programs DNA and RNA into custom 2D/3D nanoscale materials (DNA origami via the DAEDALUS algorithm) for applications spanning vaccines/therapeutics, massive molecular data storage, and β€” most relevant here β€” using DNA as a programmable scaffold to organize photonic and quantum-optical elements (mimicking quantum coherence effects seen in photosynthetic light-harvesting) and single-molecule optical biosensing.

Department(s)/lab(s): Physics / Niels Bohr Institute | BendixLab β€” Biophotonics & Mechanobiology @ UCPH
Summary:

Poul Martin Bendix (Associate Professor, BendixLab/NBI) investigates physical properties of living cells using advanced optical techniques. Research: (1) optical tweezers for mechanosensing β€” GPCR mechanosensing with picoNewton force resolution, membrane curvature sensing by proteins (annexins, BAR-domain proteins); (2) thermoplasmonics β€” gold nanoparticle laser heating for controlled membrane microsurgery, cell fusion, and plasma membrane repair; (3) single-molecule biophysics β€” DNA-protein interactions using 4-trap optical tweezers (LUMICKS C-Trap) with STED imaging; (4) filopodia dynamics β€” twist and rotation of actin filaments; (5) Brillouin microscopy for cell mechanics; (6) COBM center management. GPCRmec consortium (Novo Nordisk). 2026 BPS Annual Meeting featured.

Department(s)/lab(s): Electrical & Electronic Engineering – Photon Science Institute | Boland Group (THz Semiconductor and 2D Materials Spectroscopy) @ Manchester
Summary:

Boland's group focuses on THz spectroscopy of semiconductor nanostructures and 2D materials for quantum sensing applications. Research directions: (1) THz optical pump–THz probe spectroscopy β€” measuring ultrafast carrier dynamics in semiconductor nanowires, quantum wells, and 2D materials (graphene, TMDs, perovskites) after optical excitation; (2) Near-field THz nanoscopy β€” sub-wavelength THz imaging of carrier distributions and quantum phase domains; (3) THz-active quantum devices β€” studying exciton and polaron dynamics in perovskite and III-V semiconductors at THz frequencies; (4) 2D material sensors β€” graphene-based THz detectors and emitters. Applications in quantum-material characterization and quantum sensing.

Department(s)/lab(s): Biological Engineering | Synthetic Neurobiology Group @ MIT
Summary:

PREFERRED. Boyden co-invented optogenetics and expansion microscopy, the latter physically swelling fixed tissue in a hydrogel to achieve nanoscale-resolution imaging on conventional diffraction-limited microscopes; his Synthetic Neurobiology Group continues to push these techniques (expansion revealing, thousandfold expansion microscopy) alongside genetically encoded voltage/activity indicators and brain-wide circuit mapping. The group's Media Lab page notes it is currently accepting new students.

Department(s)/lab(s): Physics & Astronomy – Condensed Matter & Materials Physics | Breeze Lab (Solid-State Maser Quantum Sensing) @ UCL
Summary:

Breeze is a senior research fellow at UCL working on room-temperature solid-state masers. Research directions: (1) Pentacene maser β€” first demonstration of a room-temperature, continuous-wave solid-state maser (Science 2018) using photoexcited triplet-state pentacene in p-terphenyl crystal; achieving amplification with noise temperature near 1 K; (2) Diamond NV maser β€” developing NV-center-based maser for ultra-low-noise microwave amplification at room temperature, relevant to quantum sensing readout chains; (3) Maser applications β€” quantum-limited amplification for dark matter searches, MRI signal amplification, and quantum communication repeaters; (4) Spin dynamics β€” understanding triplet-state dynamics in organic crystals for spin polarization control. Strong relevance to quantum-limited microwave sensing.

Department(s)/lab(s): Imaging Physics (ImPhys) | Brinks Lab @ TU Delft
Summary:

Daan Brinks develops all-optical electrophysiology tools for neuroscience. His lab engineers genetically-encoded voltage indicators (GEVIs) and combines them with optogenetics to read out and control neural circuit activity. Key directions: (1) engineering bright, fast GEVIs with improved photostability and voltage sensitivity; (2) multiplexed all-optical neural circuit mapping; (3) identifying rare aggressive cancer cells using voltage-sensitive dyes. His voltage imaging approach represents cutting-edge biosensing at the intersection of photonics and neuroscience.

Department(s)/lab(s): Physics (Cavendish Astrophysics) | COAST / MROI Optical Interferometry Group (Buscher) @ Cambridge
Summary:

Buscher leads optical/infrared astronomical interferometry research at the Cavendish, co-leading COAST and serving as System Architect for the Magdalena Ridge Observatory Interferometer (MROI) in New Mexico. Current work focuses on MROI science-combiner instrumentation, fringe tracking, and light source/alignment systems for the beam train. He also holds an EPSRC grant (with Haniff and Young) on machining metre-sized gratings with nanometre precision for ELT high-resolution spectrographs. He is President of the Scientific Council of the European Interferometry Initiative.