Enhanced photocatalytic performance in reduced porous titanium dioxide for hydrogen production

Photocatalytic water splitting is a promising technology for hydrogen production. A key challenge for photocatalytic hydrogen generation is to find a suitable catalyst that can absorb sunlight efficiently for water splitting.

To that end, titanium dioxide (TiO₂) has been widely used as a photo-anode in the field of photo-electro-chemical (PEC) water splitting due to its chemical stability, nontoxicity, weather resistance and low cost. Nonetheless, it remains a difficulty for TiO₂ exposed to ultraviolet radiation to achieve water splitting in the absence of a photosensitizer. Moreover, the poor charge separation and slow surface reaction kinetics of TiO₂ resulted in unsatisfactory water splitting. Consequently, much effort has been undertaken to improve the photocatalytic performance of TiO₂ via elemental doping modification and the introduction of a heterojunction structure.

In a study published in the KeAi journal Advanced Powder Materials, a team of researchers from Central South University in Changsha, China, proposed a partially reduced porous TiO₂ with a graded reduction profile as a new type of photo-electrode for photocatalytic applications.

“We produced pure porous TiO₂ by freeze casting. A porous structure is considered as a feasible strategy to increase the density of highly active sites and facilitate the diffusion of reactants and products,” shares the study’s corresponding author Yan Zhang. “After carbon-thermal reduction, the phase, microstructure, conductivity and the relationship between the photocurrent density and potential of resulting partially reduced porous TiO₂ were investigated systematically.”

The researchers found that oxygen vacancy enhanced the AC conductivity of partially reduced TiO₂, which exhibited a conductivity 12 orders of magnitude higher than that of the pure TiO₂. In addition, the photocurrent density of partially porous reduced TiO₂ was 9.14 mA/cm², and the maximum value in IPCE (%) was 48 times higher than that of pure porous TiO₂.

“Our strategy entails increasing the surface area and inducing oxygen vacancies, sufficient to form a kind of electrode material with higher conductivity, thus improving electron transfer efficiency,” adds Zhang. “Furthermore, the Magnéli phase exhibits higher photoelectric conversion efficiency, which bodes well for photocatalytic applications.”

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Contact the author: Yan Zhang (yanzhangcsu@csu.edu.cn). State Key Laboratory of Powder Metallurgy, Central South University, Changsha, 410083, China

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