Silicon based MIS photoanode for water oxidation: A comparison of RuO2 and Ni Schottky contacts

“…1) can provide insight on the role of TiO 2 in IMIS performance. The values of V phot = 0.49 V and V op = −0.01 V obtained for reference MIS structure are in accordance with our previously published results [2] and indicate the state-of-the art performance of RuO 2 based MIS structure as well as good reproducibility of our technology. The IMIS structures revealed decreased Vphot from 0.49 to 0.32 V and increased V op from −0.01 to 0.18 V upon the increase of TiO 2 thickness from 0 to 6 nm.…”

“…Key part of PEC structures is the catalyst, which support high reaction rate of water oxidation. Recently, we have shown superior performance of RuO 2 / SiO 2 /n-Si compared to Ni/ SiO 2 /n-Si based metal-insulator-semiconductor (MIS) structure, which was achieved due to the high catalytic activity, good transparency, and good interface properties of RuO 2 [2]. To increase the stability of RuO 2 , it is favorable to combine it with highly corrosive resistant TiO 2 to form RuO 2 / TiO 2 bilayer catalytic gate.…”

Development and characterisation of photoelectrochemical MIS structures with RuO₂/TiO₂ gate stacs for water oxidation

“…1) can provide insight on the role of TiO 2 in IMIS performance. The values of V phot = 0.49 V and V op = −0.01 V obtained for reference MIS structure are in accordance with our previously published results [2] and indicate the state-of-the art performance of RuO 2 based MIS structure as well as good reproducibility of our technology. The IMIS structures revealed decreased Vphot from 0.49 to 0.32 V and increased V op from −0.01 to 0.18 V upon the increase of TiO 2 thickness from 0 to 6 nm.…”

“…Key part of PEC structures is the catalyst, which support high reaction rate of water oxidation. Recently, we have shown superior performance of RuO 2 / SiO 2 /n-Si compared to Ni/ SiO 2 /n-Si based metal-insulator-semiconductor (MIS) structure, which was achieved due to the high catalytic activity, good transparency, and good interface properties of RuO 2 [2]. To increase the stability of RuO 2 , it is favorable to combine it with highly corrosive resistant TiO 2 to form RuO 2 / TiO 2 bilayer catalytic gate.…”

Development and characterisation of photoelectrochemical MIS structures with RuO₂/TiO₂ gate stacs for water oxidation

“…Many insulators have been utilized in silicon‐based MIS photocatalyst systems. These include SiO 2 ,28–41 TiO 2 ,42–47 HfO 2 ,48,49 Al 2 O 3 ,42,50–53 SrTiO 3 ,54 and ZrO 2. 55 Initially, MIS systems were motivated by their ability to improve the chemical stability of semiconductors, but recently many design strategies have been identified to improve the efficiency of these systems.…”

Quantifying Losses and Assessing the Photovoltage Limits in Metal–Insulator–Semiconductor Water Splitting Systems

“…131 Thus, n-Si/SiO 2 /RuO 2 photoanodes could perform high OER performance. [132][133][134] In addition, non-noble metal and oxide/hydroxide have made outstanding contributions to reduce the overpotential of water oxidation and enhance the | 13 CHENG et al durability of Si-based photoanodes, including the bifunctional Ni-Mo, 90 Ni-Fe, 84,85,117 Fe 3 O 4 , 32 NiO x , 88,122 Co 3 O 4 , 135 NiMoO 4 , 136 and NiOOH. 71,84 And during the OER process, the surface metals are prone to be oxidized and then converted into higher active oxides/hydroxides.…”

Strategies for improving photoelectrochemical water splitting performance of Si‐based electrodes