Solar fuel production by using PV/PEC junctions based on earth-abundant materials
Paula Perez Rodriguez (TU Delft - Photovoltaic Materials and Devices)
Ibadillah Digdaya (TU Delft - ChemE/Materials for Energy Conversion and Storage)
Andrea Mangel Mangel Raventos (TU Delft - Photovoltaic Materials and Devices)
M. Falkenberg (TU Delft - Photovoltaic Materials and Devices)
R.A. Vasudevan (TU Delft - Photovoltaic Materials and Devices)
Miroslav Zeman (TU Delft - Electrical Sustainable Energy)
Wilson Smith (TU Delft - ChemE/Materials for Energy Conversion and Storage)
Arno H.M. Smets (TU Delft - Photovoltaic Materials and Devices)
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Abstract
One of the main problems of renewable energies is storage of the energy carrier. For long-term storage, solar fuels seem to be a good option. Direct solar water splitting could play an important role in the production of these solar fuels. One of the main challenges of this process is the charge separation and collection at the interfaces. The knowledge on photovoltaic (PV) junctions can be used to tackle this challenge. In this work, the use of doped layers to enhance the electric field in an a-SiC:H photocathode, and the use of thin-film silicon multijunction devices to achieve a stand-alone solar water splitting device are discussed. Using a p-i-n structure as a-SiC:H photocathode, a current density of 10mA/cm2 is achievable. The p-i-n structure proposed also indicates the suitability of traditional PV structures for solar water splitting. In addition, hybrid devices, including a silicon heterojunction PV device, are proposed. A combination of the a-SiC:H photocathode with a nc-Si:H/c-Si is demonstrated and potential STH efficiencies of 7.9% have been achieved. Furthermore, a purely PV approach such as a triple junction a-Si:H/nc-Si:H/nc-Si:H solar cell is demonstrated, with solar-to-hydrogen (STH) efficiencies of 9.8%.