A temperature- and light intensity-based methodology yields the Onset Intensity for Temperature Dependence —a newly proposed parameter that sheds light on the rate-limiting step in photocatalysis

Ishikawa, Japan -- Photocatalysis—a chemical reaction driven by light in the presence of a photocatalyst—is poised to play a key role in next-generation technologies, including hydrogen production through water splitting, carbon dioxide reduction, and environmental purification by utilizing sunlight. Thanks to these promising applications, photocatalysis is attracting attention as a major tool for building sustainable cities and societies.

However, photocatalysis involves a series of interconnected processes—light absorption, carrier excitation and transport, and surface redox reactions—that proceed in a continuous manner. This makes it challenging to identify the rate-limiting step of the overall reaction. As a result, optimizing photocatalytic reactions for maximum efficiency remains a significant challenge.

In a recent breakthrough, researchers from the Graduate School of Advanced Science and Technology at the Japan Advanced Institute of Science and Technology, Japan, led by Research Assistant Professor Yohei Cho and Professor Toshiaki Taniike, have introduced a novel methodology to pinpoint the bottleneck metrics and thus determine rate-limited regimes in photocatalysis. Their findings have been published in the Journal of Materials Chemistry A.

“In this study, we categorized photocatalytic reactions into two key processes: charge supply, which refers to the supply of excited carriers to the surface, and charge transfer, which involves redox (oxidation-reduction) reactions. Since surface reactions are more sensitive to temperature changes, we introduced the Onset Intensity for Temperature Dependence, or OITD, as a crucial metric. It marks the point at which the reaction rate begins to respond to temperature, allowing us to clearly distinguish which of the two processes is rate-limiting,” explains Dr. Cho.

The researchers measured photocatalytic reaction rates under varying temperatures and light intensities to identify the OITD and determine whether the reaction was limited by charge supply and charge transfer. Using the decomposition of methylene blue as a model reaction, they studied titanium dioxide (TiO2) and zinc oxide (ZnO) as representative photocatalysts. TiO2 exhibited temperature dependence only at high light intensity, suggesting that the material is relatively more constrained by charge supply. In contrast, ZnO showed temperature sensitivity even at lower light intensity, suggesting that its performance is relatively more limited by surface reactions. These findings reveal distinct rate-limiting behaviors for different materials. Furthermore, the study highlighted that enhancing surface accessibility through nanoparticle formation plays a more important role in improving charge supply than increasing crystallinity. This insight offers a concrete design principle for optimizing photocatalytic material design.

Dr. Cho highlights the broader impact of their findings: “Our diagnostic method supports the rational design of photocatalysts for solar-driven hydrogen production, carbon dioxide reduction, and environmental remediation. It enables rapid screening of materials and informs targeted optimization strategies—such as co-catalyst loading or nanostructuring—for efficient and practical solar energy utilization technologies. Ultimately, this can accelerate the development of sustainable energy and environmental technologies, potentially contributing to carbon neutrality and cleaner water and air.”

In conclusion, OITD offers a straightforward yet powerful diagnostic for identifying whether a photocatalytic reaction is limited by charge supply or surface charge transfer, paving the way for smarter catalyst design and improved reaction efficiency.


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Reference

Title of original paper:	Identifying Rate-Limiting Steps in Photocatalysis: A Temperature- and Light Intensity-Dependent Diagnostic of Charge Supply vs. Charge Transfer
Authors:	Yohei Cho*, Kyo Yanagiyama, Poulami Mukherjee, Panitha Phulkerd, Krishnamoorthy Sathiyan, Emi Sawade, Toru Wada, and Toshiaki Taniike*
Journal:	Journal of Materials Chemistry A
DOI:	10.1039/D5TA00415B

About Japan Advanced Institute of Science and Technology, Japan
Founded in 1990 in Ishikawa prefecture, the Japan Advanced Institute of Science and Technology (JAIST) was the first independent national graduate university that has its own campus in Japan. Now, after 30 years of steady progress, JAIST has become one of Japan’s top-ranking universities. JAIST strives to foster capable leaders with a state-of-the-art education system where diversity is key; about 40% of its alumni are international students. The university has a unique style of graduate education based on a carefully designed coursework-oriented curriculum to ensure that its students have a solid foundation on which to carry out cutting-edge research. JAIST also works closely with both local and overseas communities by promoting industry–academia collaborative research.


About Dr. Yohei Cho from Japan Advanced Institute of Science and Technology, Japan
Yohei Cho has been a Research Assistant Professor at the Materials Chemistry Frontiers Research Area, the Japan Advanced Institute of Science and Technology, Japan, since April 2025. He received his Ph.D. in 2023 from the Department of Materials Science and Technology, Tokyo Institute of Technology. His research interests include photoanodes, photocatalysts, and high-throughput experimentation. He has authored about 20 research articles in these areas, which have collectively received over 500 citations.


Funding information
This research was supported by the Grant-in-Aid for Scientific Research (No. 24KJ1201), the JST Next Generation Researcher Challenging Research Program (No. JPMJSP2102), and the Leave a Nest Research Grant KYOCERA Corporation Award.