A French-Japanese research collaboration has fabricated metal nanocomposite coatings that improve the insulating properties of window glasses. The new coating prevents a significant portion of near-infrared (NIR) and ultraviolet rays (UV) from passing through, while at the same time admitting visible light. The findings were reported in the journal İleri Malzemelerin Bilimi ve Teknolojisi.

“Although the fabrication of a commercial products is still a long way ahead, our work demonstrated a significant improvement in UV and NIR blocking properties compared to previous research,” says solid-state chemist Fabien Grasset, research director at the French National Center for Scientific Research (CNRS).

“Buildings account for a large part of global energy consumption,” explains Grasset, “with a large amount of the annual energy consumption of a standard building going to cooling and/or ısıtma sistemleri to maintain indoor temperatures at comfortable levels.” Scientists are looking for ways to develop window glass coatings that can block the entry of NIR radiation so that buildings, and even cars, can consume less energy to keep it cool inside. However, this needs to be done in a way that still allows görülebilir ışık to enter. Ideally, harmful UV rays would also be blocked.

To this end, the international French-Japanese research collaboration fabricated and analyzed the performance of nanocomposites based on niobium-tantalum cluster compounds containing chloride or bromide ions.

They found that chloride-based nanoclusters provided the best performance in terms of blocking NIR and UV rays and allowing the passage of visible light. NIR and UV blocking by the nanoclusters depended on their concentration, dispersion and oxidation state. By tuning these parameters, the team was able to improve the nanoküme performans.

The nanoclusters were dispersed into a polyvinylpyrrolidone (PVP) matrix that was then coated onto indium-tin-oxide (ITO) glass. The combination increased the transmittance of visible light while reducing that of NIR and UV rays, relative to previous research. “These are very promising NİKEL DİFÜZYON materials that block the most troublesome NIR wavelengths,” says Grasset.

“We have a long history of Japanese-French collaboration,” he continues. “We were already convinced that we are stronger working together by mixing our different cultures and ways of thinking. The international LINK project has reinforced this belief. We will continue to do our best to make further progress towards finding solutions for the global warming problem.”