Tags - (6) QuTech Delft

Department(s)/lab(s): Quantum Nanoscience | Groeblacher Lab @ TU Delft
Summary:

Simon Groeblacher's lab probes quantum physics at meso- and macroscopic scales using mechanical motion, rare-earth ion emitters, and superconducting qubits. Key research directions: (1) quantum optomechanics with photonic crystal nano-beam resonators deep in the resolved-sideband regime; (2) silicon defect emitters (rare-earth doped silicon) for quantum network nodes; (3) quantum acoustics experiments coupling mechanical resonators to superconducting qubits. The lab fabricates all devices in-house at Kavli Nanolab and has received NWO Summit Grant for 'Quantum Limits' and QDNL/NWO grant for quantum network nodes.

Department(s)/lab(s): Quantum Nanoscience | Kuipers Lab @ TU Delft
Summary:

Kobus Kuipers' lab develops and applies near-field optical microscopy to study nanophotonic phenomena with sub-wavelength spatial resolution. Research: (1) near-field imaging of topological photonic states (topological edge and interface modes in photonic crystals); (2) near-field microscopy of plasmonics and nanophotonics; (3) visualizing light transport at the nanoscale. Borderline for quantum sensing but directly relevant to nanophotonic quantum sensing platforms.

Department(s)/lab(s): Quantum Nanoscience | Rossi Lab @ TU Delft
Summary:

Massimiliano Rossi's lab focuses on levitated systems, optical tweezers, and quantum measurement. Research: (1) optically levitated nanoparticles for force sensing and zeptonewton-scale measurements; (2) quantum measurement and control of levitated systems approaching the quantum ground state; (3) back-action-evading measurement schemes for levitated oscillators; (4) exploring quantum-to-classical transitions. The lab is developing levitated systems as sensors for dark matter and gravitational waves.

Department(s)/lab(s): Quantum Nanoscience | Steele Lab @ TU Delft
Summary:

Gary Steele's lab works on quantum circuits and mechanical quantum systems, exploring quantum phenomena in nanoelectromechanical (NEMS) and superconducting circuit systems. Research includes: (1) superconducting qubit-membrane optomechanics and electromechanics; (2) circuit quantum acoustodynamics (cQAD) — coupling superconducting qubits to phonons; (3) analog quantum simulation with quantum circuits; (4) probing quantum materials (graphene, 2D materials) with superconducting circuits. The group develops novel quantum sensors for mechanical forces and electromagnetic fields.

Department(s)/lab(s): Quantum Nanoscience | Van der Sar Lab @ TU Delft
Summary:

Toeno van der Sar's group uses NV-centre diamond magnetometry to study correlated spin dynamics and electric currents in magnetic and 2D materials. Research directions: (1) scanning NV magnetometry of topological magnets, 2D magnetic materials (CrI3, Fe3GeTe2), and superconductors; (2) spin-wave (magnon) spectroscopy in magnetic thin films using NV sensors; (3) widefield NV imaging of biological samples and materials. The group develops both NV scanning probes and widefield NV ensembles for nanoscale spatial mapping of magnetic phenomena.

Department(s)/lab(s): Imaging Physics (ImPhys) | Zadeh Lab (Single-Photon Nanophotonics) @ TU Delft
Summary:

Iman Esmaeil Zadeh develops superconducting nanowire single-photon detectors (SNSPDs) and reconfigurable nano-photonic circuits. Research: (1) integrated SNSPDs with on-chip photonic waveguides and circuits for quantum optics experiments; (2) high-efficiency, low-timing-jitter SNSPDs for quantum communication and quantum sensing; (3) reconfigurable nano-photonic quantum circuits. Key enabler for quantum photonic sensing and quantum network experiments.