Our group develops a variety of innovative optical fibre devices and sensors. We go from the study of fundamental physics to the development of ruggedised portable units which include electronics/data analysis and are field deployable.
There are seven central themes to our research:
We develop photonic technologies for the next generation optical sensors of hydrocarbon and other pollutants in the ocean, with the vision to monitor organic and inorganic compounds at ppb concentrations. This project integrates photonics, electronics, surface chemical functionalization and plasmonics in a compact deployable sensor for monitoring the marine environment.
With our collaborators, we also develop fiber-based sensors for monitoring landslides, floods, seismic activity and natural disasters.
We develop fibre scintillators based on pure silica doped with small amounts of rare earths (to avoid quenching). Scintillating fibres are then connected to photomultipliers by large area conventional fibres. Multicore scintillating fibres doped with Li have been used to produce high resolution imaging of thermalised neutrons.
We develop ruggedized portable distributed sensing units for the measurement of vibrations, temperature, strain and magnetic field, using Rayleigh, Brillouin and Raman scattering.
Visit the Distributed Optical Fibre Sensing group page
We manufacture ultra-low loss waveguides, couplers, gratings, and diffractive optical elements. Our group has developed a range of optical components including: Km-long acoustically enhanced optical fibres for OTDR (optical time domain refractometry) and OFDR (optical frequency domain refractometry) systems; selective modification of fibres with complex geometry such as multicore or hollow-core fibres; optical multicore strain sensors for aerospace applications (with our collaborators at the University of the Basque Country).
Optical scattering spectrometers use scattering media to spatially decompose the spectral components of light. Each wavelength is turned by a scattering medium into a speckle pattern which serves as a unique fingerprint. With a comprehensive base of such light “fingerprints”, an unknown spectrum of light can be analysed.
We have developed a novel micro-extrusion process where a conventional 3D printer is converted into an optical fibre extrusion system. The technology is used for making suspended and hollow-core optical fibres operating in mid-IR and THz frequency domains.
Faraday rotation in novel materials with enhanced response is investigated for application in small magnetic field and single pulse detection. This project investigates the enhanced response of glasses, preliminarily observed in rare-earth fibres which showed extraordinarily large Verdet constants. Targeted applications include bulk and fibre isolators, and a variety of current and magnetic field sensors.
Discover more about research degrees and search current photonics and optoelectronics advertised projects.
