Research Areas - (443) Physics

Full path: Physics

Department(s)/lab(s): Physics | Haeffner Ion Trap Lab @ UCB
Summary:

Haeffner's group traps and coherently controls individual and few-ion crystals to perform quantum logic spectroscopy, entanglement-enhanced metrology, and quantum simulation, using trapped ions as some of the most precisely controllable quantum sensors available. The lab is actively recruiting postdocs to work on next-generation ion-trap sensing and control techniques.

Department(s)/lab(s): Electrical & Electronic Engineering – Photon Science Institute | Halsall Group (Photonics and Semiconductor Spectroscopy) @ Manchester
Summary:

Halsall is a senior PSI photonics researcher focusing on semiconductor spectroscopy and photonic quantum device characterization. Research directions: (1) Deep-level transient spectroscopy (DLTS) β€” characterizing defects and impurities in semiconductor quantum device structures (Si, GaN, SiC) that are relevant to qubit coherence; (2) Photoluminescence mapping β€” spatial mapping of optical quality in quantum well and dot wafers for quantum sensing device development; (3) InGaN/GaN quantum wells β€” non-destructive optical characterization of LED and sensor structures; (4) THz and infrared spectroscopy β€” contactless Hall measurements and Drude response for quantum material characterization. Provides photonic metrology tools for characterizing quantum sensing device materials.

Department(s)/lab(s): Electrical Engineering, Applied Physics | Donhee Ham Research Group @ Harvard
Summary:

Ham's group builds CMOS integrated-circuit platforms spanning scalable, chip-based NMR spectrometers (including impedance-tuned microwave loops for controlling dense NV-diamond spin ensembles, developed with Ronald Walsworth) and CMOS intracellular microelectrode arrays that record from thousands of neurons in parallel β€” a dual quantum-sensing/bioelectronic-sensing program built around scaling sensitive spin- and electrode-based sensors onto integrated circuits.

Department(s)/lab(s): Chemistry | Hamers Group @ UWMadison
Summary:

Studies surface and interface chemistry of diamond and other materials, including the chemical functionalization and stabilization of near-surface NV and silicon-vacancy color centers used in diamond-based quantum sensors, in collaboration with the Choy group.

Department(s)/lab(s): School of Physics | Quantum Electronic Devices Group (Hamilton) @ UNSW
Summary:

Hamilton heads the Quantum Electronic Devices group and is Deputy Director of the ARC Centre for Future Low Energy Electronics (FLEET). The group works on hole-based quantum devices in GaAs and germanium, where strong spin-orbit coupling allows all-electrical spin control, and on topological materials and one-dimensional transport. The measurements are millikelvin transport and noise spectroscopy of very small signals in mesoscopic devices. 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€” the link is indirect β€” this is charge/spin transport rather than magnetometry β€” but the group's expertise in low-noise cryogenic measurement and in spin-orbit-mediated electrical spin control is directly transferable to electrically-detected spin sensing, which is the main alternative to the optical readout that limits pT/sqrt(Hz) NV ensembles. Borderline inclusion; kept under the inclusive rubric.

Department(s)/lab(s): Chemistry | Han Laboratory @ Northwestern
Summary:

The Han Lab (Chemistry, joined fall 2023) develops quantum sensing tools rooted in electron and nuclear spin physics for life-science applications. Directions: (1) DNP-enhanced NMR quantum sensing using coupled electron-nuclear spin clusters β€” designing novel biradical and multi-spin systems achieving 700-fold ΒΉΒ³C signal enhancement at 14.1 T via P1 center clusters in HPHT diamond (exchange coupling >100 MHz); aiming for in-cell NMR with sensitivity to track water dynamics in a single cell; (2) High-field pulsed EPR at 240 GHz / 8.6 T: time-resolved Gd-Gd EPR (TiGGER) for tracking inter-residue distances during protein functional cycles in solution with sub-nm resolution; rapid-scan field-domain EPR development; (3) Integration of DNP/EPR with nanodiamond-based quantum sensors: coupled electron-nuclear spin cluster design for long-range quantum sensing in biological environments, bridging conventional NMR/EPR and NV-center-based quantum sensing. Han directs the EPR/DNP component of IMSERC (Northwestern's core facility) and brought three new EPR spectrometers and a 600 MHz DNP-NMR system.

Department(s)/lab(s): Physics / QET Labs | Harbord Group (Bristol QET Labs) @ Bristol
Summary:

Edmund Harbord researches quantum communications, solid-state quantum optics, and topological photonic structures. Research: (1) single-photon sources based on solid-state emitters (quantum dots, colour centres); (2) topological photonic crystal structures for robust quantum light propagation; (3) quantum communication protocols. Bridges photonics engineering with quantum networking.

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Department(s)/lab(s): Physics (LKB) | Quantum Optics Team (Microcavities) @ ENS Paris
Summary:

Hare works on whispering-gallery-mode microlasers and microcavities within LKB's quantum-optics research line, exploring high-Q optical microresonators for fundamental light-matter coupling studies and sensing applications.

Department(s)/lab(s): Physics, Applied Physics | Hau Lab @ Harvard
Summary:

Hau is renowned for slowing light to bicycle speed and then stopping and coherently storing optical pulses in a Bose-Einstein condensate via electromagnetically induced transparency; her current program extends this quantum-optics platform to couple light-driven photosynthetic proteins with engineered nanostructures, bridging fundamental photon physics and biophysics.

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Department(s)/lab(s): Physics (LKB) | Optomechanics and Quantum Measurements Team @ ENS Paris
Summary:

Heidmann is a founding member of LKB's cavity-optomechanics group, whose work on radiation-pressure effects, ponderomotive squeezing, and quantum-limited displacement/force measurement underpins the lab's broader precision-metrology and gravitational-wave-adjacent quantum-optics programme.