Summary
This proposed project directly address one of the priority areas outlines in EC's Green Deal programme.
The usage of textured solar cells to reduce the reflection from the air-solar cell interface, which ultimately enhances absorption, has been widely reported. There is a large number of texturing patterns available such as: pyramids, micropillars, nanowires, nanoholes, plasmonic, etc. The most commonly used patterns have been widely studied and have reached very high levels of optimisations. Nevertheless, these regular patterns have some degree of frequency dependence and hence only a narrow wavelength range optimisation, and thus limits the overall performance. Our preliminary study suggest that absorption efficiency can be further increased by at least 20%, by simply optimising the shape and periodicity of the nanowires. This proposal introduces an innovative combination of the patterns, both circular and noncircular nanowires, additionally including air-holes which increases the solar cell efficiency. Preliminary result also shows that by introducing an offset in the air-hole position, and thus breaking the symmetry, achieves an even higher conversion efficiency, but without increasing the fabrication cost, as simple single-stage mask can be used. By doing this, the improvement on the performance is expected to affect over the whole solar wavelength spectrum. Solar cells with a higher efficiency, but without increased fabrication cost can be a game changer, in supporting UN SDG7, affordable and clean energy.
Through hands-on research, the Researcher of this project will enhance his knowledge and skills so can contribute to the European Research Area agenda.
The usage of textured solar cells to reduce the reflection from the air-solar cell interface, which ultimately enhances absorption, has been widely reported. There is a large number of texturing patterns available such as: pyramids, micropillars, nanowires, nanoholes, plasmonic, etc. The most commonly used patterns have been widely studied and have reached very high levels of optimisations. Nevertheless, these regular patterns have some degree of frequency dependence and hence only a narrow wavelength range optimisation, and thus limits the overall performance. Our preliminary study suggest that absorption efficiency can be further increased by at least 20%, by simply optimising the shape and periodicity of the nanowires. This proposal introduces an innovative combination of the patterns, both circular and noncircular nanowires, additionally including air-holes which increases the solar cell efficiency. Preliminary result also shows that by introducing an offset in the air-hole position, and thus breaking the symmetry, achieves an even higher conversion efficiency, but without increasing the fabrication cost, as simple single-stage mask can be used. By doing this, the improvement on the performance is expected to affect over the whole solar wavelength spectrum. Solar cells with a higher efficiency, but without increased fabrication cost can be a game changer, in supporting UN SDG7, affordable and clean energy.
Through hands-on research, the Researcher of this project will enhance his knowledge and skills so can contribute to the European Research Area agenda.
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| Web resources: | https://cordis.europa.eu/project/id/101032153 |
| Start date: | 01-06-2021 |
| End date: | 30-06-2023 |
| Total budget - Public funding: | 224 933,76 Euro - 224 933,00 Euro |
Cordis data
Original description
This proposed project directly address one of the priority areas outlines in EC's Green Deal programme.The usage of textured solar cells to reduce the reflection from the air-solar cell interface, which ultimately enhances absorption, has been widely reported. There is a large number of texturing patterns available such as: pyramids, micropillars, nanowires, nanoholes, plasmonic, etc. The most commonly used patterns have been widely studied and have reached very high levels of optimisations. Nevertheless, these regular patterns have some degree of frequency dependence and hence only a narrow wavelength range optimisation, and thus limits the overall performance. Our preliminary study suggest that absorption efficiency can be further increased by at least 20%, by simply optimising the shape and periodicity of the nanowires. This proposal introduces an innovative combination of the patterns, both circular and noncircular nanowires, additionally including air-holes which increases the solar cell efficiency. Preliminary result also shows that by introducing an offset in the air-hole position, and thus breaking the symmetry, achieves an even higher conversion efficiency, but without increasing the fabrication cost, as simple single-stage mask can be used. By doing this, the improvement on the performance is expected to affect over the whole solar wavelength spectrum. Solar cells with a higher efficiency, but without increased fabrication cost can be a game changer, in supporting UN SDG7, affordable and clean energy.
Through hands-on research, the Researcher of this project will enhance his knowledge and skills so can contribute to the European Research Area agenda.
Status
CLOSEDCall topic
MSCA-IF-2020Update Date
28-04-2024
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