Modulated Metal-Organic Frameworks for Hydrogen Storage
Reference Number
EP/I020942/1
Title
Modulated Metal-Organic Frameworks for Hydrogen Storage
Status
Completed
Energy Categories
Hydrogen and Fuel Cells(Hydrogen, Hydrogen storage)
Research Types
Basic and strategic applied research
Science and Technology Fields
PHYSICAL SCIENCES AND MATHEMATICS (Chemistry)
ENGINEERING AND TECHNOLOGY (General Engineering and Mineral & Mining Engineering)
ENGINEERING AND TECHNOLOGY (Chemical Engineering)
ENGINEERING AND TECHNOLOGY (General Engineering and Mineral & Mining Engineering)
ENGINEERING AND TECHNOLOGY (Chemical Engineering)
UKERC Cross Cutting Characterisation
Not Cross-cutting
Principal Investigator
Professor M Schroder
Chemistry
University of Nottingham
Chemistry
University of Nottingham
Award Type
Standard
Funding Source
EPSRC
Start Date
01 October 2011
End Date
30 September 2015
Duration
48 months
Total Grant Value
£484,906
Industrial Sectors
Energy
Region
East Midlands
Programme
Energy : Energy
Other Investigator
Professor NR Champness, Chemistry, University of Nottingham
Professor S Kingman, Faculty of Engineering, University of Nottingham
Professor S Kingman, Faculty of Engineering, University of Nottingham
Web Site
Objectives
Abstract
This high-impact proposal will deliver high capacity hydrogen storage materials for applications in the automobile industry by developing the design, synthesis and scale-up of new metal-organic framework (MOF) materials. We will deliver materials with enhanced hydrogen storage capability by preparing porous MOFs with specifically designed pores for gas adsorption. These new materials will have reduced weight and volume, and thus improve overall energy storage density and efficiency. Our strategy of MOF pore modulation also develops approaches to controlling the kinetics of hydrogen uptake allowing direct management of refuelling times, and increasing the reversibility and life expectancy of the store.The proposal will deliver new methodologies for enhancing MOF structural design and synthesis by increasing hydrogen binding energies by i. formation of narrow pores thus inducing overlapping potentials from pore walls, ii. generation of free metal coordination sites within MOF pores to allow stronger binding of hydrogen directly to metal and cluster nodes, and iii. incorporation of free ligand donor sites within pores.We will develop the preparation of anionic MOFs with a range of organic, inorganic and metal counter-cations encapsulated within framework pores. Such an approach will afford materials with controlled hysteretic adsorption properties via cation gating leading to controlled refuelling/recharging of the storage system.The final aspect of the proposal will be to develop the scale-up of synthesis for selected MOFs using microwave technologies. Scale-up is a key issue for the use of MOFs in the transport sector and our approaches will target particularly high performance materials. Novel routes to functional porous materials using near critical solvents and mechanochemical methods will also be investigated. Continuous flow methods using microwave synthesis and near critical solvents will be assessed with the aim of reducing costs of scale-up.The ultimate goal of the proposal will be to bring the application of MOFs as hydrogen storage materials to a stage where they can be applied in real-world systems, thus overcoming a major technological barrier and unlocking the potential of hydrogen as a viable, clean replacement for fossil fuels, and enabling the "Hydrogen Economy" to become a reality
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Added to Database
28/11/11
