News - TEAM OF PHOTOCATALYSIS

International cooperation

1 March 2024

Throughout February, our research group had the pleasure of hosting two doctoral students (Vendula Meinhardova and Lada Dubnova) from the University of Pardubice, Czech Republic. Together, we embarked on a collaborative research journey exploring the mechanisms of heterojunction action. It was an enriching experience filled with insightful discussions and fruitful experiments. We’re grateful for the opportunity to exchange knowledge and expertise with our esteemed colleagues. Looking forward to future collaborations and discoveries!

General

Thesis defence

28 February 2024

Kamil Urbanek has got his PhD degree with distinction. Congratulations!

Photocatalytic CO₂ reduction in the presence of composites of semiconductor photocatalysts

The urgent need to address the economic and environmental challenges posed by carbon dioxide has led to a concerted effort to develop techniques for its atmospheric transformation. Photocatalysis, leveraging solar energy, emerges as a promising avenue for mitigating CO₂ levels and achieving a closed-loop carbon economy. However, traditional semiconductor photocatalysts like titanium dioxide demonstrate limited efficacy in CO₂ reduction, especially when water serves as the electron donor. As water oxidation represents a less environmentally harmful process, this thesis explores TiO₂ composites with other semiconductor photocatalysts to enhance photocatalytic activity. The investigation focuses on gas-phase reactors, enabling the utilization of air as a feed gas, thus potentially facilitating widespread adoption. A range of materials, including tin-iron, zinc-iron, cobalt, zinc-cobalt spinels, cadmium, copper and copper-cadmium sulfides, copper, tin, cerium, and tungsten oxides, and cobalt and copper tungstates, were characterized and tested for photocatalytic CO₂ reduction, either alone or in conjunction with TiO₂. While certain materials exhibited promising activity, others proved inert, even after attempts to activate them with platinum or palladium nanoparticles. Further experiments employed spectroelectrochemical techniques, photocurrent measurements, surface photovoltage measurements, and complementary oxidation processes to elucidate the mechanisms governing photocatalytic activity. Key inquiries included the potential efficiency enhancement of individual materials via composite formation, the viability of achieving S-scheme electron transfer with n-type and p-type semiconductor combinations, and the stability of multicomponent systems during photocatalytic CO₂ reduction. Results demonstrated a notable improvement in photocatalytic activity for certain composites relative to their constituent materials, with mechanisms such as heterojunctions, S-Schemes, and TiO₂ sensitization confirmed. Additionally, while combining p-type and n-type semiconductors did not always yield S-schemes or enhanced activity, the appropriate selection of materials with suitable Fermi levels proved crucial. Moreover, factors such as electrical contact between semiconductors and surface engineering influenced activity. Stability assessments revealed that some materials experienced decreased activity due to photocorrosion or active centre poisoning with CO₂ reduction products. These findings underscore the complexity of optimizing photocatalytic CO₂ reduction and highlight the importance of material selection and engineering for achieving efficient and stable systems.

Thesis defended

16 February 2024

Anna Jakimińska has got her PhD degree with distinction. Congratulations!

Processes of energy and electron transfer in photocatalytic systems containing metallic nanostructures

In this thesis, the possibility of energy or electron transfer in the systems containing titanium dioxide and various metallic nanostructures during photocatalytic processes was examined. Emphasis was placed on the elucidation of the mechanisms of plasmonic photocatalysis and the real role of metallic nanostructures in the commonly used photocatalytic systems. It was determined that metallic nanostructures, regardless of exhibiting surface plasmon resonance in visible light or not, are responsible for the decrease of the electronic states availability in the semiconductor during growth and, therefore, change in the redox properties of modified materials. Such a change might sometimes be very significant, determining the routes and nature of processes taking place in the system. Additionally, from the nucleation step, metallic nanostructures act as the electron sinks, decreasing the recombination rate and enhancing photocatalytic performance. Therefore, the universal nature of the modification of titanium dioxide with metallic nanostructures was recognized. Moreover, the extraordinary use of plasmonic modes in photocatalysis is presented, i.e., the remote photocatalysis with the propagating surface plasmon polaritons of single silver nanowires that enables excitation of the photocatalytic system without direct irradiation. The demonstration of such a possibility may open a new avenue for constructing photocatalytic systems with higher performance and plasmonic nanostructures.

Conference

12th Czech – Polish Catalytic Symposium

12 February 2024

Our results were presented at the 12^th Czech – Polish Catalytic Symposium, held in Ostrava, Czech Republic, on February 9^th, 2024. We have presented 2 lectures. As always, the symposium was full of interesting presentations and inspiring scientific discussion.

Grant

New group member

6 February 2024

The Team of Photocatalysis has a new member, Dr. Paweł Wyżga joined us as a post-doc, and he will be working on the OPUS23 project.

Cooperation

Scientific cooperation

20 November 2023

YOSHIDA Ken-ichi

We hosted Prof. Minoru MIZUHATA (Department of Chemical Science and Engineering, Kobe University), who gave a lecture on the synthesis of oxide systems and, in particular liquid phase deposition methods (electrolytic deposition). After the lecture, we spent time discussing the direction of research within the Opus 24 project, in which we cooperated with Prof. Mizuhata.

General

Visiting researcher

15 November 2023

At the end of October, we had the pleasure of hosting Dr. Milda Petruleviciene from the State Research Institute Center for Physical Sciences and Technology, Lithuania. During her month-long stay in our laboratories, Dr. Petruleviciene conducted intensive research on the photoelectrochemical properties of the imported materials. We hope that the cooperation established in this way will result in joint publications and projects in the future.

Award

1 October 2023

Dr Kasidid Yaemsunthorn received the award for best oral presentation in the V Autumn Meeting of the Polish Photochemistry Group Molecules & Light 2023.

Conference

Molecules & Light

27 September 2023

We were honoured to host the V Autumn Meeting of the Polish Photochemistry Group, also known as ‘Molecules & Light.‘ This gathering, organized by the Polish section of the EPA, aimed to bring together researchers in the fields of photophysics, photochemistry, photocatalysis, and molecular spectroscopy. The event welcomed 86 participants, not only from Poland but also from countries including the USA, Germany, Italy, the Czech Republic, Slovakia, and Saudi Arabia. Throughout the meeting, we had the privilege of enjoying six outstanding plenary lectures, 39 inspiring oral presentations, and 37 impressive poster presentations.

Thesis defended

22 September 2023

Kasidid Yaemsunthorn has got his PhD degree. Congratulations!

Phase-Dependent Photocatalytic Activity of TiO₂ – the Role of Intrinsic and Extrinsic Factors

The doctoral thesis delves into the phase-dependent photoactivity of anatase and rutile TiO₂, explored through various photocatalytic reactions involving oxidation and reduction processes. The investigation of the influential factors involved in this dependency has led to the identification of two primary categories: intrinsic factors, which relate to the physicochemical and characteristic properties of the materials themselves, and extrinsic factors, which are associated with the nature of the specific reactions and their corresponding reaction conditions. The study demonstrates that the photoactivity of TiO₂ is relative to both intrinsic and extrinsic factors, and sheds light on the mechanisms underlying photocatalysis. By optimizing these factors, it is possible to enhance the photoactivity of TiO₂ and develop more efficient and practical photocatalytic systems. These findings reveal the fundamental mechanisms underlying photocatalysis and pave the way for the development of more suitable photocatalysts for particular reactions, which are crucial for optimizing and realizing the practical use of photocatalysis for addressing the energy crisis and climate change.