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Russian Scientists Unveil Solar-Powered Water Purification Breakthrough

Scientists at the Moscow Institute of Physics and Technology have developed a new class of photocatalysts that use visible sunlight to purify water. The breakthrough overcomes a key limitation, as most existing catalysts only work with ultraviolet light, which is a small fraction of solar radiation. Using a technique called femtosecond laser ablation, the team created nanoparticles from niobium-based compounds, with lithium niobate proving most effective. This nanocatalyst significantly boosted dye degradation rates, paving the way for scalable, solar-powered water treatment systems.

Key Points: New Solar Catalyst Purifies Water Using Visible Light

  • Uses visible sunlight, not just UV
  • Femtosecond laser ablation creates nanoparticles
  • Lithium niobate catalyst most effective
  • Achieves 90% purification in 150 minutes
2 min read

Russian scientists develop high-efficiency solar catalysts for water purification

Russian scientists develop high-efficiency photocatalysts using visible sunlight for eco-friendly water purification, a major sustainable tech advance.

"laser processing altered each material differently... lithium niobate maintained its crystalline framework but developed controlled point defects. - Research Team"

Moscow, February 20

Scientists at the Moscow Institute of Physics and Technology have developed a new class of photocatalysts capable of purifying water using visible sunlight, marking a major step forward in sustainable water treatment technologies, according to the institute's official website.

The research was conducted by experts from MIPT's Centre for Photonics and Two-Dimensional Materials in collaboration with international partners. The team identified the most efficient material structure for photocatalytic activity within the visible light spectrum, as reported by TV BRICS.

According to TV BRICS, Photocatalysis is considered a promising method for removing organic pollutants such as dyes, pharmaceutical residues, pesticides and oil traces from water. However, most existing photocatalysts function mainly under ultraviolet light, which constitutes only about 5 per cent of the solar spectrum. In comparison, visible light accounts for nearly half of solar radiation, making its utilisation vital for developing scalable and environmentally friendly technologies.

To overcome this challenge, researchers employed femtosecond laser ablation in liquids, a technique involving ultra-short, high-energy laser pulses that vaporise material surfaces. The vapour subsequently condenses into nanoparticles with customised electronic properties. Importantly, the process generates stable colloidal solutions in water without requiring surfactants, ensuring a clean and eco-friendly synthesis method.

The scientists examined two niobium-based compounds: niobium pentoxide (Nb₂O₅) and lithium niobate (LiNbO₃). Findings revealed that laser processing altered each material differently. Nb₂O₅ lost its crystalline structure and became completely amorphous, while the more thermodynamically stable LiNbO₃ maintained its crystalline framework but developed controlled point defects.

While amorphous materials tend to trap and neutralise light-induced charge carriers quickly, controlled defects in crystalline structures enhance visible light absorption and extend charge carrier lifetimes. This enables reactive species formation that effectively breaks down pollutants.

Laboratory experiments showed that the lithium niobate-based nanocatalyst increased dye degradation rates by 2.3 times compared to amorphous niobium oxide, achieving 90 per cent purification within 150 minutes. Researchers aim to further optimise the method and expand it for real-world solar-powered water treatment applications.

- ANI

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Reader Comments

P
Priya S
Great to see international collaboration on such a critical issue. The focus on using visible sunlight is key for tropical countries like India where we have abundant sunshine. I wonder about the cost of the femtosecond laser technique though – will it be scalable for mass production?
R
Rohit P
Impressive science, but 150 minutes for 90% purification? That seems quite slow for practical, large-scale use. Our cities need systems that can process millions of liters daily. The principle is sound, but the speed needs major improvement before it's a real-world solution.
S
Sarah B
As someone working in environmental tech, this is a significant breakthrough. The move away from UV to visible light addresses a major efficiency bottleneck. The clean synthesis method is also a big plus. Curious to see how it handles complex industrial waste versus simple dyes.
K
Kavya N
This gives me hope! So many villages rely on contaminated groundwater. A solar-powered unit based on this could be a game-changer. Hope our CSIR or IITs pick up on this research and develop localized versions. Jai Vigyan! 🙏
M
Michael C
The materials science here is fascinating – the difference between amorphous and crystalline structures with controlled defects. It shows how precise engineering at the nano-level can unlock new functionalities. A great step for sustainable chemistry.

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