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Projects: Projects for Investigator
Reference Number EP/P030068/1
Title Surface Engineering Solid State Dye-Sensitized Solar Cells
Status Completed
Energy Categories Renewable Energy Sources(Solar Energy, Photovoltaics) 100%;
Research Types Basic and strategic applied research 100%
Science and Technology Fields PHYSICAL SCIENCES AND MATHEMATICS (Chemistry) 25%;
ENGINEERING AND TECHNOLOGY (Mechanical, Aeronautical and Manufacturing Engineering) 25%;
UKERC Cross Cutting Characterisation Not Cross-cutting 100%
Principal Investigator Dr PJ Holliman
No email address given
Bangor University
Award Type Standard
Funding Source EPSRC
Start Date 01 September 2017
End Date 30 August 2021
Duration 48 months
Total Grant Value £345,084
Industrial Sectors Energy
Region Wales
Programme Energy : Energy
Investigators Principal Investigator Dr PJ Holliman , Chemistry, Bangor University (100.000%)
  Industrial Collaborator Project Contact , Pilkington Group Ltd (0.000%)
Project Contact , G24 Power (0.000%)
Project Contact , BIPVCo (0.000%)
Web Site
Abstract Dye-sensitized solar cells (DSC) can be described as a form of "artificial photosynthesis" because, in both cases, light is harvested by a pigment (chlorophyll in photosynthesis or a synthetic dye in DSC). This is interesting because photosynthesis is ~5% efficient in terms of the incident light energy (i.e. photons) captured to the energy in the photosynthetic by-products. Despite this apparently low efficiency, photosynthesis has supported the planet's biosphere for aeons. One reason for this is the huge amount of sunlight which reaches the Earth's surface every day. This has been estimated to be ~6,000x more than annual global energy consumption despite the growing global population using huge amounts of energy. Given that the sun will last for billions more years, sunlight is vastly more abundant than any other energy source currently available. In this context, if we use 10% efficient PV, using only 0.2% of the Earth's surface would meet energy demands whilst releasing only trace greenhouse gases during production and none during operation. This will slow the accelerating pace of fossil fuel related climate change.Whilst PV uptake has increased hugely recently (~11GW in UK and >225GW globally), this still represents a tiny fraction of current energy demand; the question is why? Crystalline Si PV currently dominates the market (~90%) but is heavy, rigid and is usually made from batch-like processes into limited product forms (rectangular, encapsulated, glass panels). And despite these products being available for many years, they are still bolted onto frames attached onto existing roofs with wires often running across open roof-space. They do not fit, they are a "bolt-on" solution.This research will develop PV which can be printed by continuous (roll-to-roll, R2R) processing. Because R2R is faster than batch processing, it will reduce manufacturing costs but increase the amount of product which can be made. R2R product can also be made to any length or width which will revolutionise PV product form. Perhaps most importantly, by varying the PV substrate, this will enable PV to be fully integrated into roof/wall panels or windows. This will drastically reduce installation and balance of systems costs (i.e. PV panel mounting system, DC/AC power inverters, wiring, switches, battery storage) which make up almost half of the cost of most PV installations.DSC technology is already in commercial production (www.gcell.co.uk) and is already known to be suitable for R2R processing. In addition, DSC raw materials are non-toxic and abundant. Whilst DSC device lifetimes >25,000h have been reported (equivalent to ~25y operation), the liquid electrolytes used can leak and are corrosive to some metals which increases substrate costs. This proposal will exchange this liquid electrolyte for a solid, charge carrier to make solid state DSC (ssDSC) devices to avoid these issues. Whilst ssDSC have been made before, it has been difficult to control their construction because this involves depositing 2 thin layers of different chemicals onto porous metal oxide particles in a porous film. The resulting inconsistent layer coverage causes energy losses which limits device efficiency. To overcome this, we will use self-assembling molecules and computer modelling to explore surface chemistry/structure to speed-up the research. Thus, we will design dyes and charge carriers to behave like "self-parking cars in a car park" and move to the correct position before fixing themselves in place. Then, by controlling the self-assembly process, we will add multiple dyes into the device to increase light harvesting to improve device efficiency to reduce pay-back times; i.e. the time when the customer has saved enough money on their energy bills to pay off the system purchase costs. By combining computer modelling and experiment, we will cut design to manufacture times up to 10-fold by reducing the number of material modification cycles required
Publications (none)
Final Report (none)
Added to Database 15/02/19