Tags - (14) CQSE Manchester

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): Chemistry – Photon Science Institute / National EPR Facility | Bowen Group (Molecular Spin Qubits and EPR) @ Manchester
Summary:

Bowen leads the CQSE 'Spins and Qubits' theme at Manchester, focusing on organometallic molecular spin qubits for quantum sensing and computing. Research directions: (1) Organometallic La(II) and other rare-earth molecular qudits β€” designing molecules with multiple accessible spin states (qudits) for encoding quantum information and sensing; (2) Pulsed EPR characterization β€” Hahn echo, ESEEM, ENDOR at X/W/Q-band to measure coherence times and hyperfine couplings; (3) Integration of molecular qubits into devices β€” surface deposition and nanoscale addressing; (4) Multi-spin sensing β€” using exchange-coupled spin pairs as differential sensors of magnetic field gradients. Closely collaborates with Tuna and Winpenny.

Department(s)/lab(s): Electrical & Electronic Engineering – Photon Science Institute | Curry Group (Advanced Electronic Materials and Quantum Technologies) @ Manchester
Summary:

Curry's group works on advanced electronic materials with emphasis on quantum technology applications. Research directions: (1) Single-ion implantation and detection β€” using P-NAME (Manchester's unique instrument for ion implantation at 20 nm accuracy) to deterministically place single rare-earth ions (Er3+, Pr3+) in photonic substrates for quantum memory and sensing; (2) Er:Si and Er:SiO2 photonics β€” developing silicon-compatible Er-doped waveguides and cavities emitting at 1.5 Β΅m for quantum network interfaces; (3) Colloidal quantum dots for sensing β€” photon-number-resolved detection using InAs QDs; (4) Ion beam technologies β€” SIMS and focused ion beam for quantum material characterization and fabrication. Access to P-NAME facility is unique in UK.

Department(s)/lab(s): Chemistry – Photon Science Institute | Gardner Group (Analytical and Biomedical Spectroscopy) @ Manchester
Summary:

Gardner's group develops infrared and Raman microspectroscopy for biomedical diagnostics and disease sensing. Research directions: (1) FTIR synchrotron microspectroscopy β€” using Diamond Light Source synchrotron IR beam for high-spatial-resolution chemical mapping of biological tissues for cancer diagnosis; (2) Raman microspectroscopy β€” label-free chemical imaging of cells and tissue for disease classification using machine-learning chemometrics; (3) SERS probes β€” developing gold nanoparticle SERS labels for targeted cancer biomarker detection; (4) Breathomics β€” on-chip photonic sensors for exhaled breath analysis for early disease detection. The infrared and Raman methods provide label-free molecular sensing with potential for quantum-enhanced sensitivity.

Department(s)/lab(s): Physics & Astronomy – Photon Science Institute | Graham Group (SERS and Nanoplasmonic Biosensing) @ Manchester
Summary:

Graham's group develops SERS-based nanoplasmonic sensing platforms for biomedical applications. Research directions: (1) SERS nanogap substrates β€” engineering colloidal gold and silver nanostructure clusters with reproducible, high-enhancement nanogaps for single-molecule SERS detection; (2) In vivo SERS β€” intravenous SERS nanotags for tumor imaging and multiplexed biomarker detection in living organisms; (3) Microfluidic SERS β€” integrating SERS probes in microfluidic channels for continuous monitoring of circulating biomarkers; (4) Quantitative SERS β€” calibration strategies for absolute analyte quantification for clinical diagnostics. Extreme sensitivity (single-molecule) relevant to quantum-enhanced optical sensing.

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): Physics & Astronomy – Photon Science Institute | Hibberd Group (THz Spectroscopy and Quantum Materials) @ Manchester
Summary:

Hibberd holds an EPSRC Ernest Rutherford Fellowship at Manchester's PSI. Research directions: (1) Ultrafast THz spectroscopy of magnetic materials β€” probing spin dynamics, magnon modes, and phase transitions in correlated magnetic materials with sub-ps time resolution using intense THz pulses; (2) THz-driven spintronics β€” using THz electric and magnetic fields to switch magnetization and induce spin currents; (3) THz generation from spintronic heterostructures β€” using ultrafast spin-charge conversion as a broadband THz emitter for materials characterization; (4) Quantum magnonics β€” studying collective spin excitations (magnons) as quantum sensors of materials order parameters. Bridges ultrafast optics and quantum sensing of magnetic phases.

Department(s)/lab(s): Physics & Astronomy | Quantum Technologies for Fundamental Physics Group (McDonald Group) @ Manchester
Summary:

McDonald leads the Quantum Technologies for Fundamental Physics (QTFP) theme at CQSE Manchester. Research directions: (1) Manchester Axion Novel Cavity eXperiment (MANCX) β€” building a cavity haloscope to search for QCD axions and axion-like particles coupling to photons via resonant microwave cavity enhancement at Manchester; (2) Astroparticle theory β€” superradiance from black holes for ultralight dark matter/axion bounds; neutron star probes of new physics; (3) Dark energy / extended gravity β€” vacuum energy and Casimir-type effects; (4) High-frequency gravitational waves β€” novel detection concepts. Workshop chair for Manchester's QTFP international workshop (Jan 2026). Interdisciplinary collaboration with quantum engineers, low-temperature physicists, and particle physicists.

Department(s)/lab(s): Chemistry – National Electron Paramagnetic Resonance Facility | National EPR Facility / McInnes Group @ Manchester
Summary:

McInnes leads the National EPR Facility at Manchester (Europe's broadest EPR suite) and researches molecular spin qubits. Research directions: (1) Pulsed EPR spectroscopy of molecular spin systems β€” Hahn echo, ESEEM, ENDOR, DEER for structural and electronic characterization of inorganic and organometallic complexes; (2) Molecular spin qubits β€” [Cu(mnt)2]²⁻ and related molecules as candidate qubits; measuring coherence times and investigating decoherence mechanisms; (3) Multi-qubit molecular registers β€” using exchange interactions for two-qubit gates within a molecule; (4) Magnetic sensing applications β€” molecular systems for magnetic field sensing below the diffraction limit. Partner of NPL M4Q EPSRC Network for Materials for Quantum.

Department(s)/lab(s): Chemistry – Photon Science Institute | Natrajan Group (Lanthanide Photophysics and Biosensing) @ Manchester
Summary:

Natrajan's group develops luminescent lanthanide complexes for chemical and biological sensing. Research directions: (1) Time-gated lanthanide luminescence sensing β€” long-lifetime Eu3+, Tb3+, and Yb3+ complexes with millisecond emission lifetimes for background-free sensing in cells and tissue; (2) Intracellular sensing β€” luminescent probes for sensing O2, pH, viscosity, and specific enzymes inside living cells with spatiotemporal resolution; (3) Chiral discrimination β€” circularly polarized luminescence (CPL) from Eu3+ complexes for enantioselective sensing; (4) Responsive probes β€” switchable lanthanide complexes as ratiometric sensors for biomedical imaging. The long-lifetime emission enables time-gating strategies analogous to quantum sensing protocols.