Scientists use lasers and gold particles to turn titanium oxide into nanocomposite for photocatalysts
Oxides of different metals often serve as photocatalysts in various systems such as air purification, reactions of water decomposition and even in the production of self-cleaning surfaces for glass and mirrors. The physical-chemical properties of such materials can be improved by adding nanoparticles, which turn an ordinary oxide into a nanomaterial with new capabilities. To successfully perform this, however, it is necessary to understand the processes going on as a nanocomposite is being formed, and to be able to control them. ITMO University researchers together with their colleagues from France and the USA have demonstrated how a femtosecond laser can be used to tune the structure and nanocomposite properties for titanium dioxide films filled with gold nanoparticles. The paper was published in ACS the Journal of Physical Chemistry C.
Some time ago, scientists and engineers created a number of special materials capable of accelerating chemical processes when exposed to light. This discovery has a great implications for industry – such materials can be used in a wide variety of devices, from air purifiers to fuel cells. One of such promising materials is titanium dioxide, which can be infused with gold nanoparticles to improve its photocatalytic properties. Research in this field is conducted by ITMO University researchers.
In fact, fabrication of such composite materials remains challenging. Thin films of titanium dioxide and gold nanoparticles can be created separately, but the way of combination of these two components is yet to be established. There are certain difficulties with placing nanoparticles inside the oxide films, and it’s even more difficult to control their size and distribution. An international group of researchers, including those from ITMO University, has suggested using laser radiation to achieve this goal.
“If we subject these materials to laser radiation, both the gold particles and the titanium dioxide matrices around them change their properties,” explains Maksim Sergeev, a research associate at ITMO.
The researchers from ITMO University and the Hubert Curien Laboratory have carried out an experiment, where thin films of poriferous titanium dioxide were impregnated with gold ions rapidly forming particles on the scale of a few nanometers. Then, the material was subjected to laser radiation. It turned out that with the properly chosen femtosecond laser irradiation, it is possible to effectively control the growth of nanoparticles without damaging the material. For instance, if the laser is moving at a very low speed, cavities may form around the newly grown nanoparticles in the titanium dioxide film.
“Together with researchers from the University of Arizona we developed a model to explain this effect that helped us to determine the temperature field in the material when it was subjected to laser radiation.. The model considered resonant absorption on metal particles, local field enhancement, photoinduced generation of unbound electrons, and photoemission. The material turned out to heat more when it contained both smaller and larger particles, though its temperature was still not high enough to melt or destroy the material for the correctly chosen laser parameters,” elaborates Tatiana Itina, Research Director at the Hubert Curien Laboratory of the French National Center for Scientific Research.
As a result of both experiments and simulations, the researchers can now better understand the mechanisms behind nanocomposite film formation and have more possibilities to control their properties. Using lasers for these purposes will simplify the production of such “gold-plated” titanium dioxide films, which will make it easier to implement them in the industry. Right now, however, the technology is far from being ready and additional studies are underway.