Back-illuminated Si photocathode: a combined experimental and theoretical study for photocatalytic hydrogen evolution

Si is an excellent absorber material for use in 2-photon photoelectrochemical hydrogen production. So far nearly all studies of silicon photoelectrodes have employed frontal illumination despite the fact that in most water-splitting 2-photon device concepts the silicon is the “bottom” cell in the tandem stack and therefore illuminated from the back with respect to the electrolyte. In the present work, we investigate back-illuminated Si photoelectrodes experimentally, as well as by modelling, the dependence of induced photocurrent on various parameters, such as carrier diffusion length (Le) and surface recombination velocity (vs) to quantify their relative importance. A bifacial light absorbing structure (p+pn+ Si) is tested under back-illumination conditions which mimic the actual working environment in a tandem water splitting device. The thickness of the absorbing Si layer is varied from 30 to 350 μm to assess the impact of the diffusion length/thickness ratio (Le/L) on photocatalytic performance. It is shown how the induced photocurrent (JL) of a back-illuminated sample increases as wafer thickness decreases. Compared to the 350 μm thick sample, a thinned 50 μm thick sample shows a 2.7-fold increase in JL, and consequently also a higher open circuit voltage. An analytical model is developed to quantify how the relative Le/L-ratio affects the maximum JL under back-illumination, and the result agrees well with experimental results. JL increases with the Le/L-ratio only up to a certain point, beyond which the surface recombination velocity becomes the dominant loss mechanism. This implies that further efforts should to be focused on reduction of surface recombination. The present study is the first experimental demonstration of a Si wafer based photocathode under back-illumination. Moreover, the comparative experimental and theoretical treatment also highlights which photoabsorber properties merit the most attention in the further development towards full tandem water splitting devices.

[1]  Ib Chorkendorff,et al.  Bioinspired molecular co-catalysts bonded to a silicon photocathode for solar hydrogen evolution. , 2011, Nature materials.

[2]  V. Milichko,et al.  Photo-induced electric polarizability of Fe3O4 nanoparticles in weak optical fields , 2013, Nanoscale Research Letters.

[3]  Matthew R. Shaner,et al.  Electrical and Photoelectrochemical Properties of WO3/Si Tandem Photoelectrodes , 2013 .

[4]  R. Margolis,et al.  A wafer-based monocrystalline silicon photovoltaics road map: Utilizing known technology improvement opportunities for further reductions in manufacturing costs , 2013 .

[5]  Ib Chorkendorff,et al.  Solar-fuel generation: Towards practical implementation. , 2012, Nature materials.

[6]  Nathan S. Lewis,et al.  Photoelectrochemical water splitting: silicon photocathodes for hydrogen evolution , 2010, Optics + Photonics for Sustainable Energy.

[7]  Ib Chorkendorff,et al.  Using TiO2 as a conductive protective layer for photocathodic H2 evolution. , 2013, Journal of the American Chemical Society.

[8]  N. Wyrsch,et al.  Bifacial a-Si:H solar cells: Origin of the asymmetry between front and back illumination , 2007 .

[9]  Mark Kerr,et al.  Surface passivation of silicon solar cells using plasma-enhanced chemical-vapour-deposited SiN films and thin thermal SiO2/plasma SiN stacks , 2001 .

[10]  Jan Augustynski,et al.  Highly efficient water splitting by a dual-absorber tandem cell , 2012, Nature Photonics.

[11]  A. Bard Photoelectrochemistry and heterogeneous photo-catalysis at semiconductors , 1979 .

[12]  S. Glunz,et al.  Carrier-selective contacts for Si solar cells , 2014 .

[13]  Matthew R. Shaner,et al.  Photoelectrochemistry of core–shell tandem junction n–p^+-Si/n-WO_3 microwire array photoelectrodes , 2014 .

[14]  Christophe Ballif,et al.  Amorphous Si thin film based photocathodes with high photovoltage for efficient hydrogen production. , 2013, Nano letters.

[15]  Nathan S. Lewis,et al.  An analysis of the optimal band gaps of light absorbers in integrated tandem photoelectrochemical water-splitting systems , 2013 .

[16]  Ib Chorkendorff,et al.  Bio-inspired co-catalysts bonded to a silicon photocathode for solar hydrogen evolution , 2011, Optics + Photonics for Sustainable Energy.

[17]  T. Buonassisi,et al.  Light-induced water oxidation at silicon electrodes functionalized with a cobalt oxygen-evolving catalyst , 2011, Proceedings of the National Academy of Sciences.

[18]  Optimization of Recombination Layer in the Tunnel Junction of Amorphous Silicon Thin-Film Tandem Solar Cells , 2011 .

[19]  James R. McKone,et al.  Solar water splitting cells. , 2010, Chemical reviews.

[20]  J. Turner A Nickel Finish Protects Silicon Photoanodes for Water Splitting , 2013, Science.

[21]  Jun Kubota,et al.  Stable hydrogen evolution from CdS-modified CuGaSe2 photoelectrode under visible-light irradiation. , 2013, Journal of the American Chemical Society.

[22]  R. L. Mattis,et al.  Resistivity‐Dopant Density Relationship for Boron‐Doped Silicon , 1980 .

[23]  S. Dahl,et al.  Hydrogen production using a molybdenum sulfide catalyst on a titanium-protected n(+)p-silicon photocathode. , 2012, Angewandte Chemie.

[24]  D. Rose,et al.  SunPower's Maxeon Gen III solar cell: High efficiency and energy yield , 2013, 2013 IEEE 39th Photovoltaic Specialists Conference (PVSC).

[25]  K. McIntosh,et al.  Light‐enhanced surface passivation of TiO2‐coated silicon , 2012 .

[26]  Robert Schlögl,et al.  Chemistry's role in regenerative energy. , 2011, Angewandte Chemie.

[27]  Turner,et al.  A monolithic photovoltaic-photoelectrochemical device for hydrogen production via water splitting , 1998, Science.

[28]  D. Losee,et al.  Admittance spectroscopy of impurity levels in Schottky barriers , 1975 .

[29]  Michael Grätzel,et al.  Hydrogen evolution from a copper(I) oxide photocathode coated with an amorphous molybdenum sulphide catalyst , 2014, Nature Communications.

[30]  Wilhelmus M. M. Kessels,et al.  Silicon passivation and tunneling contact formation by atomic layer deposited Al2O3/ZnO stacks , 2013 .

[31]  Miro Zeman,et al.  Efficient solar water splitting by enhanced charge separation in a bismuth vanadate-silicon tandem photoelectrode , 2013, Nature Communications.

[32]  Thomas F. Jaramillo,et al.  Addressing the Terawatt Challenge: Scalability in the Supply of Chemical Elements for Renewable Energy , 2012 .

[33]  Nathan S Lewis,et al.  Photoelectrochemical hydrogen evolution using Si microwire arrays. , 2011, Journal of the American Chemical Society.

[34]  A. Rohatgi,et al.  Aluminum alloy back p–n junction dendritic web silicon solar cell , 2001 .

[35]  Chenming Calvin Hu,et al.  Solar cells : from basics to advanced systems , 2012 .

[36]  Kyoung-Shin Choi,et al.  Nanoporous BiVO4 Photoanodes with Dual-Layer Oxygen Evolution Catalysts for Solar Water Splitting , 2014, Science.

[37]  Shyam S. Kocha,et al.  Photoelectrochemical decomposition of water using modified monolithic tandem cells fn2 fn2 Presented , 1999 .

[38]  N. Lewis,et al.  Powering the planet: Chemical challenges in solar energy utilization , 2006, Proceedings of the National Academy of Sciences.

[39]  P. Fath,et al.  Bifacial Solar Cells on Multi-Crystalline Silicon with Boron BSF and Open Rear Contact , 2006, 2006 IEEE 4th World Conference on Photovoltaic Energy Conference.