Nanostructured Functional Materials for Energy Efficient Refrigeration, Energy Harvesting and Production of Hydrogen from Water.
Lead Research Organisation:
Imperial College London
Department Name: Materials
Abstract
This program is about using nanostructured materials to address key areas in energy related applications. This proposal will deliver world class materials science through ambitious thin and thick film development and analysis and the proposal targets the EPSRC strategic areas Energy and Nanoscience through nanoengineering. The programme grant will provide the opportunity to integrate three well established research areas that currently operate independently of each other and will establish a new consortium of activities. Collectively they offer the essential ingredients to move this particular field forward. The planned program of work is timely because of the convergence of modelling capability, precision multilayer oxide growth expertise and nanofabrication facilities. The overall vision for the Programme Grant is focussed on Energy. Within the Programme we aim to find means of reducing energy consumption for example by using electro and magnetocaloric means of cooling; generating energy by use of nanoscale rectifying antennas and finally storing energy by photocatalytic splitting of hydrogen from water. Our program is divided into two themed areas:1) Nanostructured oxides for Energy Efficient Refrigeration with 2 project areasElectrocaloricsMagnetocalorics2) Nanostructured oxides for energy production and storage with 2 project areasSolar HarvestingPhotocatalysisThis research will enable :- The development of new materials, new material architectures and new device concepts for energy refrigeration and energy harvesting. The synergy across a range of programs particularly the underpinning activities of materials theory, modelling and characterisation will move these important fields closer to application.- The research will also enable a new forum to be established, with representation from UK and European scientists and industrialists so that broad discussions can be held to enable moving these fields forward. We place a significant emphasis on training, outreach and knowledge transfer.The research challenges that need to be addressed are:- Designing physical systems that are close to an instability so that small external perturbations from magnetic or electric fields, optical or thermal excitation will tip the system into a new ground state- Optimising control over (strain, defects, doping inhomogeneity, disorder) and first layer effects in thin film oxides (with thicknesses of the order of 10nm or less) so that we can develop the capability to tune the band gap of the oxide using directed modelling and targeted growth control.
Organisations
- Imperial College London (Lead Research Organisation)
- University of Cambridge (Project Partner)
- Leibniz Institute for Solid State and Materials Research (Project Partner)
- The Welding Institute (Project Partner)
- Daresbury Laboratory (Project Partner)
- Iowa State University (Project Partner)
- Camfridge (United Kingdom) (Project Partner)
- National Physical Laboratory (Project Partner)
- Ericsson (Sweden) (Project Partner)
- Netzsch (United Kingdom) (Project Partner)
- University of Nova Gorica (Project Partner)
Publications
Dunne L
(2011)
Statistical mechanical lattice model of the dual-peak electrocaloric effect in ferroelectric relaxors and the role of pressure
in Journal of Physics D: Applied Physics
Bartok A
(2016)
Study of the first paramagnetic to ferromagnetic transition in as prepared samples of Mn-Fe-P-Si magnetocaloric compounds prepared by different synthesis routes
in Journal of Magnetism and Magnetic Materials
Altynnikov A
(2014)
Suppression of slow capacitance relaxation phenomenon in Pt/Ba0.3Sr0.7TiO3/Pt thin film ferroelectric structures by annealing in oxygen atmosphere
in Applied Physics Letters
Wells MP
(2018)
Temperature stability of thin film refractory plasmonic materials.
in Optics express
Schmidgall E
(2010)
Temperature stable BaxSr1-xTiO3 thin film structures for microwave devices
in Electronics Letters
Baumfeld O
(2014)
The dynamics of spontaneous hydrogen segregation in LaFe13- x Si x H y
in Journal of Applied Physics
Waske A
(2016)
The impact of surface morphology on the magnetovolume transition in magnetocaloric LaFe 11.8 Si 1.2
in APL Materials
Valant M
(2012)
The Origin of Magnetism in Mn-Doped SrTiO 3
in Advanced Functional Materials
Donchev E
(2014)
The rectenna device: From theory to practice (a review)
in MRS Energy & Sustainability
Description | The project examines 4 areas. Electrocaloric materials that can change temperature on the application of a voltage, magnetocaloric materials that can change temperature on the application of a magnetic field, a rectifying antenna structure that can harvest incoming radiation (solar or infra red), and finally the catalytic dissociation of water to produce hydrogen. Findings so far: Electrocalorics Three key summary points that are priorities i) device set-up of a DSC-based direct-EC measurement system; ii) development of theoretical models describing the Electrocaloric effect; iii) synthesis of highly polarisable and anisotropic ceramics Magnetocalorics • Comparative study of manganites verses competitive materials • Optimisation of MCE with grain size and anisotropy • Assessments of the benefits of new material architectures Rectenna • Identification of suitable materials and device architecture • Development of nano-antennas • Manufacturing of MIM diodes Solar Hydrogen • Development of a theoretical model for complex charge transport in the semiconducting nanostructures. • Development of a model to assess photocatalytic performance. • Characterisation of the electronic structure of the nanostructures. |
Exploitation Route | The work described in this grant will lead to routes that will: Save energy (electrocaloric and magnetocaloric cooling) Produce energy by rectification of incoming radiation Store energy by producing hydrogen from water and storing the hydreogen Through industrial partners |
Sectors | Electronics,Energy,Environment,Security and Diplomacy |
Description | The magnetocalorics research was of direct benefit to a company - Camfridge. |
First Year Of Impact | 2013 |
Sector | Energy,Environment |
Impact Types | Economic |
Description | Nanoscale Advanced Materials Engineering |
Amount | £7,671,801 (GBP) |
Funding ID | EP/V001914/1 |
Organisation | Engineering and Physical Sciences Research Council (EPSRC) |
Sector | Public |
Country | United Kingdom |
Start | 07/2021 |
End | 06/2026 |
Description | "Electrocalorics -A new solid state cooler" |
Form Of Engagement Activity | A talk or presentation |
Part Of Official Scheme? | No |
Primary Audience | |
Results and Impact | Anna-Karin Axelsson "Electrocalorics -A new solid state cooler" invited presentation, 13th April 2012, University of Nova Goricia , Slovenia. |
Year(s) Of Engagement Activity | 2012 |