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Combining photocatalytic collection and degradation of microplastics using self-asymmetric Pac-Man TiO <sub>2</sub>

Nanoscale 2023 40 citations ? Citation count from OpenAlex, updated daily. May differ slightly from the publisher's own count. Score: 50 ? 0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.

Maria Camila Ariza-Tarazona, Maria Camila Ariza-Tarazona, Maria Camila Ariza-Tarazona, Maria Camila Ariza-Tarazona, Erika Iveth Cedillo-González Purnesh Chattopadhyay, Purnesh Chattopadhyay, Purnesh Chattopadhyay, Erika Iveth Cedillo-González Maria Camila Ariza-Tarazona, Erika Iveth Cedillo-González Erika Iveth Cedillo-González Purnesh Chattopadhyay, Purnesh Chattopadhyay, Erika Iveth Cedillo-González Erika Iveth Cedillo-González Cristina Siligardi, Purnesh Chattopadhyay, Cristina Siligardi, Cristina Siligardi, Cristina Siligardi, Maria Camila Ariza-Tarazona, Erika Iveth Cedillo-González Cristina Siligardi, Maria Camila Ariza-Tarazona, Maria Camila Ariza-Tarazona, Cristina Siligardi, Erika Iveth Cedillo-González Juliane Simmchen, Juliane Simmchen, Erika Iveth Cedillo-González Erika Iveth Cedillo-González Erika Iveth Cedillo-González Erika Iveth Cedillo-González Cristina Siligardi, Cristina Siligardi, Erika Iveth Cedillo-González Cristina Siligardi, Juliane Simmchen, Juliane Simmchen, Erika Iveth Cedillo-González Juliane Simmchen, Juliane Simmchen, Juliane Simmchen, Cristina Siligardi, Cristina Siligardi, Cristina Siligardi, Cristina Siligardi, Juliane Simmchen, Erika Iveth Cedillo-González Erika Iveth Cedillo-González Juliane Simmchen, Erika Iveth Cedillo-González Juliane Simmchen, Juliane Simmchen, Juliane Simmchen, Juliane Simmchen, Erika Iveth Cedillo-González Juliane Simmchen, Erika Iveth Cedillo-González Erika Iveth Cedillo-González Cristina Siligardi, Erika Iveth Cedillo-González Erika Iveth Cedillo-González Erika Iveth Cedillo-González Cristina Siligardi, Cristina Siligardi, Erika Iveth Cedillo-González Erika Iveth Cedillo-González Erika Iveth Cedillo-González Erika Iveth Cedillo-González

Summary

Researchers developed a self-asymmetric Pac-Man-shaped TiO2 micromotor that combines self-propulsion, phoretic collection, and photocatalytic degradation to efficiently capture and break down microplastics in water.

Polymers

Microplastics are a significant environmental threat and the lack of efficient removal techniques further amplifies this crisis. Photocatalytic semiconducting nanoparticles have the potential to degrade micropollutants, among them microplastics. The hydrodynamic effects leading to the propulsion of micromotors can lead to the accumulation of microplastics in close vicinity of the micromotor. Incorporating these different properties into a single photocatalytic micromotor (self-propulsion, phoretic assembly of passive colloids and photocatalytic oxidation of contaminants), we achieve a highly scalable, inherently-asymmetric Pac-Man TiO<sub>2</sub> micromotor with the ability to actively collect and degrade microplastics. The target microplastics are homogeneous polystyrene microspheres (PS) to facilitate the optical degradation measurements. We cross-correlate the degradation with catalytic activity studies and critically evaluate the timescales required for all involved processes.

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