Nagoya Institute of Technology Scientists Develop an All-in-One Catalyst for Solar-Driven Water Remediation

NAGOYA, Japan, March 24, 2025 /PRNewswire/ -- Reliable access to clean water is a basic human right and a central objective of the United Nations' Sustainable Development Goals. Thus, securing technologies that can remove pollutants from water bodies is an essential step toward sustainability. Among several existing methods, harnessing solar energy represents an attractive option for water remediation without increasing carbon emissions.

Many photocatalysts are currently being explored for degrading water pollutants via solar-driven reactions. Photothermal evaporation, on the other hand, uses solar energy to rapidly evaporate polluted water and condense it into fresh water. Unfortunately, photocatalytic and photothermal water remediation technologies tend to rely on expensive materials that are challenging to synthesize and implement at large scales, necessitating the development of a single and inexpensive composite material.

In a recent study, a research team comprising Dr. Kunihiko Kato, Dr. Yunzi Xin, and Mr. Yuping Xu, all from the Nagoya Institute of Technology (NITech), Japan, led by Associate Professor Takashi Shirai also from NITech, developed a novel method to synthesize multifunctional composite particles. These particles can single-handedly accomplish many essential functions for water remediation. Their study was made available online on October 1, 2024, and was published in Volume 16, Issue 4 of ACS Applied Materials & Interfaces on December 4, 2024.

The researchers employed a planetary ball mill and optimized the milling parameters to transform the commercially available powdered mixture of molybdenum trioxide (MoO₃) and polypropylene into composite particles made of hydrogen molybdenum bronze (H_xMoO_3–y), molybdenum dioxide (MoO₂), and activated carbon. "The proposed mechanochemical process surpasses other current approaches in terms of both energy efficiency and cost-effectiveness," highlights Dr. Shirai.

Through extensive experimentation, the research team demonstrated the many remarkable capabilities of their composites. First, these particles exhibited broad light absorption over the entire near-infrared–visible–ultraviolet range, allowing the photocatalytic degradation of a model organic pollutant. Interestingly, the composites also functioned as Brønsted acid catalysts and removed water pollutants even in the absence of light.

Additionally, the proposed catalyst exhibited plasmonic properties, leading to a marked photothermal effect that enabled rapid heating using sunlight. This could be leveraged to drive the fast evaporation of water with exceptional photothermal conversion efficiency. Finally, oxygen-containing carbons that remained as milling byproducts could adsorb and remove heavy metal ions from wastewater.

The research team plans to refine their ball milling process to produce similar all-in-one catalysts for water remediation and other applications. "Our developed technology has the potential to be applied to a wide range of oxides and plastics, and we anticipate that it will have varied applications, including enhancing the functionality of existing materials and upcycling waste plastics to secure the availability of drinking water," concludes Dr. Shirai.

Watch a video summarizing their research here: https://youtu.be/Vy3IdbNS4os

Reference
Title of original paper: Multifunctional H_xMoO_3−y−MoO₂/Carbon Composite Particles for Water Remediation
Journal: ACS Applied Materials & Interfaces
DOI: 10.1021/acsami.4c09169

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SOURCE Nagoya Institute of Technology