Silicon nanowire-hydrogenated TiO2 core-shell arrays for stable electrochemical micro-capacitors

In this paper, we fabricated silicon nanowire-TiO2 core-shell arrays in a two-step process. First, silicon nanowire arrays (SiNW) were prepared in HF/AgNO3 aqueous solution using metal-assisted chemical etching of bulk silicon. Then, atomic layer deposition (ALD) technique was applied to coat a 20 nm thin shell TiO2 film. The TiO2/SiNW substrates were afterward annealed at 400 degrees C in hydrogen atmosphere for 4 h and tested as electrode materials for electrochemical micro-capacitors. The electrochemical features of the constructed H-TiO2/SiNW electrode were assessed in an aqueous 1 M Na2SO4 electrolyte solution and revealed that the specific capacitance increased six times compared to non-annealed TiO2/SiNW and 20-fold compared to a reference SiNW electrode under the same operating conditions. Importantly, H-TiO2/SiNW also displayed a high stability over 30,000 cycles at 0.1 mA cm(-2) with an overall decrease of 19% of the initial capacitance. The hydrogen treatment increased the density of hydroxyl group and enhanced the carrier density on TiO2 surface improving the capacitive properties of H-TiO2/SiNW. (C) 2021 Elsevier Ltd. All rights reserved.

Automated summary

In this study, silicon nanowire-TiO2 core-shell arrays were fabricated and treated with hydrogen, demonstrating improved capacitance and stability in electrochemical performance.