Imaging is an important aspect of photonics research across many departments within the University. We are constantly applying ourselves to the generation of novel methodologies, hardware and processing techniques for enhanced image formation. Research is focussed to improve spatial and temporal resolution, acquiring data from a wide range of processes and is applied acoss a broad variety of specimens.
My group studies mechanisms and machines of gene expression using single-molecule biophysical methods and biochemistry.
Our group uses high-resolution optical microscopy to unravel the coding strategies employed in sensory representation and memory storage.
My research focuses on understanding the interactions of supramolecular complexes that form the structural elements of cells and carry out essentially all functions and processes within living cells.
My research interests lie in the theory and practice of dynamic optics, particularly the use of adaptive optical elements in high resolution microscopy and ultrafast laser fabrication.
Photonics is one of the tools that helps me to study embryogenesis, by imaging cell movements and fate during early mouse development.
The focus of our research is the development of selective molecular probes to enable investigation of certain biological systems. Our interest in photonics is particularly related photochemical biology and the development of "caged" compounds.
The optical research of the group has the aim of enabling our collaborators to perform effective research by offering advanced microscopy techniques in a form that can be used routinely.
My research is in the area of acoustics, primarily focused on biomedical acoustics with applications in both diagnostics and therapeutics. My interests in photonics lie in acousto-optic sensing, which have so far been applied to thermally induced lesions in tissue.
My research group develops and applies linear and non-linear optical diagnostic techniques to solve problems in thermofluids including heat transfer, mixing and combustion.
We are working in soft condensed matter with a focus on the phase, interface and flow behaviour of colloidal particles. Our main experimental technique is optical microscopy, which includes confocal microscopy, fluorescence and simple video-microscopy (homemade and commercial microscopes).
We combine advanced imaging and computational techniques to study the musculoskeletal system.
My research is concerned with the development and application of spectroscopic and imaging tools designed to visualise, study and eventually control dynamic processes in chemistry and biology.
Our research in neuroscience is supported by the development of novel optical imaging tools, particularly through high resolution microscopy.
The main research interests of my laboratory are focused on the application and development of ultra-sensitive, live-cell fluorescence microscopy techniques with a spatial resolution down to the molecular level.
I am interested in all aspects of optical microscopy, but in particular those systems which offer three dimensional resolution in the image.
My laboratory is focused on the development of fluorescence imaging approaches capable of showing the spatial and temporal regulation of protein-protein interactions and/or enzymatic activity inside living cells and animals.
I use the techniques of X-ray crystallography and X-ray microscopy to study the structural biology of viruses. Viruses are attractive targets for study at the molecular level, since they are sufficiently simple that we may hope to achieve a rather complete understanding of their biology.
My research involves bionanotechnology and its application to cancer. Some of our photonics related research includes the development of new ways to target quantum dots (QDots) and conjugated polymer dots (Pdots), ultra-bright nanoparticles, to study cell surface receptors.
My research interests are focused around applying state of the art instrumentation in surface science to novel problems. This has lead me into a wide range of fields including, amongst others, nanotechnology, electrochemistry and biotechnology.
I use adaptive optics enabled ophthalmoscopes as a tool to investigate visual perception, aiming to answer such questions as "How do the neural circuits in human retina process colour information?".
Our group does research in the areas of molecular materials synthesis, supramolecular chemistry, molecular recognition, polymers and dyes. All work is directed towards the design and creation of new molecular materials with useful optical, electronic or biomedical properties.
We are working in soft condensed matter in general with an emphasis on colloids. Our main experimental technique is optical microscopy, which includes confocal microscopy, fluorescence and simple video-microscopy (homemade and commercial microscopes).
Our research is aimed at enhancement our understanding of complex biological processes through the analysis of image data.
I am the facility manager of the Wolfson Imaging Centre, based in the Weatherall Institute of Molecular Medicine. We specialise in methods of fluorescence imaging, including single molecule and super-resolution (STED, STORM/PALM).
I design CMOS Image Sensors and micro/nano electromechanical sensors, for applications in transportation as well as commercial imaging.
For more information, please send me an email.
I manage the live cell imaging systems and software at the Micron centre for advanced bioimaging.
Yvonne Jones is director of the Cancer Research UK Receptor Structure Research Group which is primarily focused on the structural biology of cell surface recognition and signalling complexes.
My research interests include molecular electronics, nano-scale chemistry and sensory interfaces.
My research focuses on the application of physical acoustics principles to problems in biomedical acoustics, industrial ultrasonics, acoustical oceanography, and biomedical imaging and therapy at the intersection of light and sound.
My research is focused on rotary molecular motors, in particular the Bacterial Flagellar Motor, which is a rotary molecular engine powered by the flow of ions across the inner, or cytoplasmic, membrane of a bacterial cell envelope.
I’m interested in the effect of defects on material properties, ranging from single atom defects, such as vacancies and interstitials, to extended defects, such as dislocations, to macroscopic defects, for example cracks and voids.
My interests in photonics lie in advanced light microscopy techniques, as a route to the study biomolecules ideally within the context of living cells.
A new cross-departmental consortium has been announced following the award of funding from the MRC/BBSRC/EPSRC and other bodies. This will involve development of new super resolution optical nanoscopes. Several research groups within the Oxford Photonics network will be contributing expertise.
The third Oxford Photonics day was held on Tuesday 12th March 2013. Around 70 researchers from across the University, with additional external guests participated in a successful event. Prizes for best Student Oral and Poster presentations were awarded.
We are pleased to announce the date for the next Oxford Photonics Day, which has been set for Tuesday 8th October 2013 (0th week) and will take place in the Department of Engineering Science. More details are to follow in the coming few weeks.
Two new Royal Society University Research Fellows, Dr Brian Patton and Dr Josh Nunn, have recently started new research programmes in Photonics.
The 6th Oxford Photonics Day is due to be held on Wednesday 8th Oct in the Thom Building, Lecture Room 1, in the Engineering Department in Oxford.
I-CASE EPSRC Studentship advertised: applications wanted! Check out the advert:
Congratulations to Professor Martin Booth who has been awarded the 2014 International Commission for Optics (ICO) Prize “for his innovative and pioneering research on dynamic optical methods and new approaches to adaptive optics”.
University of Oxford has been chosen to lead one of the four Quantum Hubs in the £120m Quantum Technology programme. Optical physicist Professor Ian Walmsley will lead a consortium of academic and industrial partners to deliver quantum technologies ...
We are pleased to announce the date for the 7th Oxford Photonics Day, which has been set for Monday 20th April 2015 (0th week, Trinity term). It will be held at the Department of Engineering Science. The event will be free to attend for members of the Oxford Photonics Network. The programme will include...
Engineers and Scientists around the world are getting ready for the 2015 International Year of Light (IYL). This International Year has been the initiative of a large consortium of scientific bodies together with UNESCO. The 2015 IYL will consist of ...
The 7th Photonics Day will be held on 20th April 2015. We once again look forward to a set of lively talks ranging from application of quantum dots to optical sensing of nucleic acids. Speakers come from across Oxford and the UK.
Please register here: http://goo.gl/forms/3Pe4PkS0dh
Here is the workshop programme:
Oxford researchers led by Dr Gil Bub have used optogenetic methods to stimulate heart cells in order to elucidate the operation of muscle excitation waves.
The Optical Society (OSA) has published a brochure about how optics and photonics impacts the global economy.