Small items of research equipment at the University of Oxford
Lead Research Organisation:
University of Oxford
Department Name: Oxford Physics
Abstract
This is an enabling grant that will support a wide range of early career researchers (ECRs) and fields of research across the engineering and physical science remit. The majority of the activities can be grouped together within one of three broad themes:
- The development of novel physical science methodologies and analytical techniques and their application to the biological sciences and medicine.
- Quantum phenomena and systems, including research into superconductors and other quantum materials, and the development of quantum circuits and quantum computing devices.
- Advanced materials engineering. Key areas of activity include metalorganic frameworks (including methodologies for synthesis of new MOFs and the design of novel polymer nanocomposites containing MOFs) and structural engineering materials.
- The development of novel physical science methodologies and analytical techniques and their application to the biological sciences and medicine.
- Quantum phenomena and systems, including research into superconductors and other quantum materials, and the development of quantum circuits and quantum computing devices.
- Advanced materials engineering. Key areas of activity include metalorganic frameworks (including methodologies for synthesis of new MOFs and the design of novel polymer nanocomposites containing MOFs) and structural engineering materials.
Planned Impact
The breadth of research that will be supported through this grant has the potential for impact across a wide range of different sectors.
Development and application of novel physical methods has the potential to deliver major impacts within the pharmaceutical, biotechnology and healthcare sectors. In particular, they offer the prospect of increasingly personalised healthcare - for example, through the development of novel drugs (with far more selective targeting) or the fabrication of biomimetic scaffolds to aid tissue regeneration. Research enabled through this grant also has the potential for major benefits in the agricultural and food sectors - for example, by reducing the uptake in rice of arsenic and other toxins.
Quantum mechanics underpins much of modern physics and provides powerful tools for understanding physical systems. Scientific advances in quantum phenomena have the potential to impact on a wide variety of beneficiaries outside of academia through the development of new technologies. For example, the exploitation of quantum entanglement to enable quantum communication, quantum cryptography, and quantum computing have had profound effects on our understanding of such systems and have wide reaching impacts on the future of computing, security and cryptography. Similarly, research in quantum materials has the potential to revolutionise the electronics, medicine, energy and computing sectors by creating novel components and sensors. A particular focus of current Oxford research is on optical quantum memory which offers dramatically increased rates of data transfer.
Several strands of research will also contribute to carbon reduction, with the potential for widespread societal impact (behavioural change) and environmental benefits. Improving the cost-effectiveness of solar cell technology has the potential to greatly increase uptake. Next-generation battery management systems are essential for roll-out of electric and hybrid vehicles. Novel, lightweight materials for use in engine parts have the potential to improve fuel efficiency and so reduce carbon emissions.
New bio-mechanics and bio-engineering insights will inform the design of submersible vehicles, with potential implications for both defence and civilian use.
Development and application of novel physical methods has the potential to deliver major impacts within the pharmaceutical, biotechnology and healthcare sectors. In particular, they offer the prospect of increasingly personalised healthcare - for example, through the development of novel drugs (with far more selective targeting) or the fabrication of biomimetic scaffolds to aid tissue regeneration. Research enabled through this grant also has the potential for major benefits in the agricultural and food sectors - for example, by reducing the uptake in rice of arsenic and other toxins.
Quantum mechanics underpins much of modern physics and provides powerful tools for understanding physical systems. Scientific advances in quantum phenomena have the potential to impact on a wide variety of beneficiaries outside of academia through the development of new technologies. For example, the exploitation of quantum entanglement to enable quantum communication, quantum cryptography, and quantum computing have had profound effects on our understanding of such systems and have wide reaching impacts on the future of computing, security and cryptography. Similarly, research in quantum materials has the potential to revolutionise the electronics, medicine, energy and computing sectors by creating novel components and sensors. A particular focus of current Oxford research is on optical quantum memory which offers dramatically increased rates of data transfer.
Several strands of research will also contribute to carbon reduction, with the potential for widespread societal impact (behavioural change) and environmental benefits. Improving the cost-effectiveness of solar cell technology has the potential to greatly increase uptake. Next-generation battery management systems are essential for roll-out of electric and hybrid vehicles. Novel, lightweight materials for use in engine parts have the potential to improve fuel efficiency and so reduce carbon emissions.
New bio-mechanics and bio-engineering insights will inform the design of submersible vehicles, with potential implications for both defence and civilian use.
Organisations
People |
ORCID iD |
Ian Walmsley (Principal Investigator) |
Publications
Grabarczyk DB
(2014)
Infrared spectroscopy provides insight into the role of dioxygen in the nitrosylation pathway of a [2Fe2S] cluster iron-sulfur protein.
in Journal of the American Chemical Society
Quinson J
(2014)
Comparison of carbon materials as electrodes for enzyme electrocatalysis: hydrogenase as a case study
in Faraday Discuss.
Chaudhari AK
(2015)
Multifunctional Supramolecular Hybrid Materials Constructed from Hierarchical Self-Ordering of In Situ Generated Metal-Organic Framework (MOF) Nanoparticles.
in Advanced materials (Deerfield Beach, Fla.)
Ash PA
(2015)
Electrochemical and Infrared Spectroscopic Studies Provide Insight into Reactions of the NiFe Regulatory Hydrogenase from Ralstonia eutropha with O2 and CO.
in The journal of physical chemistry. B
Hidalgo R
(2015)
Infrared Spectroscopy During Electrocatalytic Turnover Reveals the Ni-L Active Site State During H2 Oxidation by a NiFe Hydrogenase.
in Angewandte Chemie (International ed. in English)
Titov K
(2016)
Facile patterning of electrospun polymer fibers enabled by electrostatic lensing interactions
in APL Materials
Ash PA
(2016)
Synchrotron-Based Infrared Microanalysis of Biological Redox Processes under Electrochemical Control.
in Analytical chemistry
Paengnakorn P
(2017)
Infrared spectroscopy of the nitrogenase MoFe protein under electrochemical control: potential-triggered CO binding.
in Chemical science
Coates C
(2017)
Large elastic recovery of zinc dicyanoaurate
in APL Materials