Insights into the degradation of microplastics by Fenton oxidation: From surface modification to mineralization

David Ortiz; Macarena Munoz; Julia Nieto-Sandoval; Cristina Romera-Castillo; Zahara M de Pedro; Jose A Casas

doi:10.1016/j.chemosphere.2022.136809

Insights into the degradation of microplastics by Fenton oxidation: From surface modification to mineralization

Chemosphere. 2022 Dec;309(Pt 2):136809. doi: 10.1016/j.chemosphere.2022.136809. Epub 2022 Oct 10.

Authors

David Ortiz¹, Macarena Munoz², Julia Nieto-Sandoval³, Cristina Romera-Castillo⁴, Zahara M de Pedro³, Jose A Casas³

Affiliations

¹ Chemical Engineering Department, Universidad Autonoma de Madrid, Ctra. Colmenar Km 15, 28049, Madrid, Spain. Electronic address: david.ortiz@uam.es.
² Chemical Engineering Department, Universidad Autonoma de Madrid, Ctra. Colmenar Km 15, 28049, Madrid, Spain. Electronic address: macarena.munnoz@uam.es.
³ Chemical Engineering Department, Universidad Autonoma de Madrid, Ctra. Colmenar Km 15, 28049, Madrid, Spain.
⁴ Instituto de Ciencias del Mar-CSIC, Paseo Maritimo de la Barceloneta, 37, 08003, Barcelona, Spain.

PMID: 36228721
DOI: 10.1016/j.chemosphere.2022.136809

Abstract

This work aims at evaluating the fate of microplastics (MPs) along Fenton oxidation. For such goal, realistic MPs (150-250 μm) of five representative polymer types (PET, PE, PVC, PP and EPS) were obtained from commercial plastic products by cryogenic milling. Experiments (7.5 h) were performed under relatively severe operating conditions: T = 80 °C; pH₀ = 3; [H₂O₂]₀ = 1000 mgL^-1 (15 doses, 1 every 0.5 h); [Fe³⁺]₀ = 10 mgL^-1 (5 doses, 1 every 1.5 h). Slight MPs weight losses (∼10%) were achieved after Fenton oxidation regardless the MP nature. Nevertheless, oxidation yield clearly increased with decreasing the particle size given their higher exposed surface area (up to 20% weight loss with 20-50 μm EPS MPs). Clearly, MPs suffered important changes in their surface due to the introduction of oxygenated groups, which made them more acidic and hydrophilic. Furthermore, MPs progressively reduced their size. In fact, they can be completely oxidized to CO₂, as demonstrated in the oxidation of PS nanoplastics (140 nm), where 70% mineralization was achieved. The nature of the plastic particles had a relevant impact on its overall oxidation, being more prone to be oxidized those polymers which contain aromatic rings in their structures (EPS and PET) compared to those formed by alkane chains (PE, PP and PVC). In the latter, the presence of substituents also reduced their oxidation potential. Remarkably, possible leachates released along reaction were more quickly oxidized than the MPs/NPs, so it can be assumed that these dissolved compounds would be completely removed once the solid particles are eliminated. Notably, the leachates obtained upon MPs oxidation were more biodegradable than the released from the fresh solids. All this knowledge is crucial for the understanding of MPs oxidation by the Fenton process and opens the door for the design and optimization of this technology either for water treatment or for analytical purposes (MPs isolation).

Keywords: Fenton oxidation; Microplastic; Nanoplastic; Polystyrene.

MeSH terms

Alkanes
Carbon Dioxide
Hydrogen Peroxide / chemistry
Microplastics*
Plastics*
Polyvinyl Chloride

Substances

Microplastics
Plastics
Hydrogen Peroxide
Carbon Dioxide
Polyvinyl Chloride
Alkanes