Thursday, October 19, 2023

 

Safely removing nanoplastics from water using 'Prussian blue', a pigment used to dye jeans


Microplastics can be removed by 99% with flocculants alone, without any additional equipment, by irradiating them with sunlight


Peer-Reviewed Publication

NATIONAL RESEARCH COUNCIL OF SCIENCE & TECHNOLOGY

Figure 1 

IMAGE: 

NANOPLASTIC TREATMENT USING FEHCF NANOBOTS UNDER VISIBLE-LIGHT IRRADIATION

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CREDIT: KOREA INSTITUTE OF SCIENCE AND TECHNOLOGY




Plastic waste breaks down over time into microplastics (<0.1 μm). Microplastics smaller than 20 μm cannot be removed in currently operating water treatment plants and must be agglomerated to a larger size and then removed. Iron (Fe) or aluminum (Al) based flocculants are used for this purpose, but they are not the ultimate solution as they remain in the water and cause severe toxicity to humans, requiring a separate treatment process.

Dr. Jae-Woo Choi of the Center for Water Cycle Research at the Korea Institute of Science and Technology (KIST) has developed an eco-friendly metal-organic skeleton-based solid flocculant that can effectively aggregate nanoplastics under visible light irradiation.

Prussian blue, a metal-organic frameworks-based substance made by adding iron (III) chloride to a potassium ferrocyanide solution, is the first synthetic pigment used to dye jeans a deep blue color and has recently been used to adsorb cesium, a radioactive element, from Japanese nuclear plant wastewater. While conducting experiments on the removal of radioactive materials from water using Prussian blue, the KIST research team discovered that Prussian blue effectively aggregates microplastics under visible light irradiation.

The research team developed a material that can effectively remove microplastics by adjusting the crystal structure to maximize the aggregation efficiency of Prussian blue. When the developed material is irradiated with visible light, microplastics with a diameter of about 0.15 μm (150 nm), which are difficult to remove using conventional filtration technology, can be agglomerated to a size about 4,100 times larger, making them easier to remove. In experiments, the researchers found that they were able to remove up to 99% of microplastics from water. The developed material is also capable of flocculating microplastics more than three times its own weight, outperforming the flocculation efficiency of conventional flocculants using iron or aluminum by about 250 times.

The material not only uses Prussian blue, which is harmless to the human body, but is also a solid flocculant, making it easy to recover residues in water. It also uses natural light as an energy source, enabling a low-energy process.

"This technology has a high potential for commercialization as a candidate material that can be applied to general rivers, wastewater treatment facilities, and water purification plants," said Dr. Choi of KIST. "The developed material can be utilized not only for nanoplastics in water, but also to clean up radioactive cesium, thus providing safe water." Meanwhile, Dr. Youngkyun Jung, the first author of the paper, said, "The principle of this material can be utilized to remove not only microplastics, but also a variety of contaminants in water systems."

Schematics of the preparation of the FeHCH nanobots and process for NP removal

CREDIT

Korea Institute of Science and Technology


Supplementary Video [VIDEO] |

Formation of the FeHCF@NP complex under visible-light irradiation

KIST was established in 1The sources of photos and research results from KIST must be specified.Formation of the FeHCF@NP complex under visible-light irradiation966 as the first government-funded research institute in Korea. KIST now strives to solve national and social challenges and secure growth engines through leading and innovative research. For more information, please visit KIST’s website at https://eng.kist.re.kr/

The research, which was supported by the Ministry of Science and ICT (Minister Lee Jong-ho) through the Material Innovation Leading Project (2020M3H4A3106366) and the KIST Institutional Project (2E32442), was published on October 1 in the international journal Water Research.

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