Objective 1: minimize bulk recombination: suppress microscopic point defects such as vacancies and macroscopic defects such as grain boundaries in order to increase the lifetime of minority charge carriers: With an optimized deposition condition the defect structure could be drastically reduced and heteroepitaxial film stack was developed.[1] This resulted in pinhole free films as evidenced by the ability to make measurements in H2O2 containing electrolyte. The electrochemical measurements were all consistent with one another and the optics of the system could be well described by calculation, showing that Al2O3(0001)/Pt(111)/alpha-Fe2O3(0001) heteroepitaxial photoanodes serve as an excellent model system for investigation of hematite properties.
Objective 2: minimizing failures: reduce defects such as pinholes and cracks within the individual thin films and the whole stack: With improved deposition condition and post-deposition thermal treatment the performance and stability was increased.[2–5] Crack free thin films can be deposited by lowering the deposition temperature. Thermal treatment improves photoelectrochemical performance in hematite thin films both in low onset potential and high photocurrent density. In addition the underneath lying substrate was optimized to reduce the defect density and roughness drastically.[3,6–8] This also leads to high specular reflectivity.
Objective 3: optimizing the coupling between the photoelectrolytic cell and the photovoltaic cell in the tandem-cell: First steps to couple the photoelectrochemical cell with a photovoltaic cell was performed by investigating wavelength-selective dielectric mirrors (distributed Bragg reflectors, DBR).[9] Different multilayer stacks were simulated and the selected structures were fabricated and tested. Thin film alpha-Fe2O3 photoanodes deposited on DBR stacks were found to show a photocurrent enhancement compared to similar photoanodes on transparent substrates.
Objective 4: optimizing the fabrication by avoiding incompatible processing conditions: This allowed implementation into a flip-over process to increase the specular reflectivity and therefore the device performance.[4] The film transfer process was invented to allow high temperature hematite processing while avoiding tarnishing the metallic back reflector.[3,6–8] Through this flip transfer process an absorbed photocurrent of more than 9 mA/cm2 was achieved for an ultra-thin hematite film. Our work shows the high potential of hematite as photoanode material in photoelectrolysis using thin film technology.
Objective 5: production of a prototype water splitting device: scale up from 1x1cm3 to 10x10cm3 devices:
For scale up ultrasonic spray pyrolysis and sputtering deposition techniques were investigated as in-house pulsed laser deposition only allows the deposition of samples with 2 cm2.[2] For both methods suitable deposition conditions were found, which lead to similar performances as the PLD deposited films. With ultrasonic spray pyrolysis (USP) a 10x10 cm2 cell was fabricated.
[1] D. A. Grave, H. Dotan, Y. Levy, Y. Piekner, B. Scherrer, K. D. Malviya, A. Rothschild, J. Mater. Chem. A 2015, 0, 1.
[2] D. Shai Ben, S. Barbara, R. Avner, The effect of thermal treatment on the performance of the hematite photoanodes; 2017.
[3] B. Scherrer, A. Key, Y. Piekner, K. D. Malviya, D. Grave, H. Dotan, A. Rothschild, Prep. 2017.
[4] K. D. Malviya, B. Scherrer, D. Shlenkevich, A. Tsyganok, H. Mor, H. Dotan, A. Rothschild, Prep. 2017.
[5] B. Scherrer, T. Li, B. Gupta, M. Doebeli, K. D. Malviya, B. Gault, O. Kasian, N. Maman, I. Visoly-Fischer, Raabe, Dierk, A. Rothschild, Prep. 2017.
[6] A. Kay, M. Leben, K. D. Malviya, H. Dotan, A. Rothschild, B. Scherrer, In Gordon Research Conferences: Renewable Energy: Solar Fuels; 2016.
[7] A. Kay, M. Leben, K. D. Malviya, H. Dotan, A. Rothschild, B. Scherrer, In Material Research Society Spring 2016; 2016.
[8] B. Scherrer, A. Kay, H. Dotan, A. Rothschild, In Material Research Society Fall 2016; 2016.
[9] Y. Piekner, H. Dotan, K. D. Malviya, B. Scherrer, A. Rothschild, In 17th Israel Materials Engineering Conference (IMEC-17); 2016.