Separation of Microplastic Particles from Sewage Sludge Extracts Using Magnetic Seeded Filtration

Frank Rhein; Hermann Nirschl; Ralf Kaegi

doi:10.1016/j.wroa.2022.100155

Separation of Microplastic Particles from Sewage Sludge Extracts Using Magnetic Seeded Filtration

Water Res X. 2022 Sep 13:17:100155. doi: 10.1016/j.wroa.2022.100155. eCollection 2022 Dec 1.

Authors

Frank Rhein¹, Hermann Nirschl¹, Ralf Kaegi²

Affiliations

¹ Karlsruhe Institute of Technology (KIT), Institute of Mechanical Process Engineering and Mechanics Strasse am Forum 8, Karlsruhe 76131 Germany.
² Eawag, Ueberlandstrasse 133, Dübendorf 8600 Switzerland.

Abstract

Microplastic particles (MP) are efficiently retained in wastewater treatment plants and enriched in sewage sludge. For monitoring MP contents in wastewater systems, sewage sludge is thus well suited, but also requires an isolation of MP from the sludge matrix, as other sewage sludge components may interfere with the MP identification and quantification. Although organic matter in sludge samples can be removed through acid and enzymatic digestion procedures, cellulose - mainly from toilet paper - remains in the digests, due to its high chemical resistivity and similar density to MP. We apply the separation concept of magnetic seeded filtration to isolate MP through selective hetero-agglomeration with magnetic seed particles. MP and cellulose differ in their hydrophobic properties and we investigate to what extent these differences can be exploited to selectively form MP-magnetite hetero-agglomerates in the presence of cellulose. These hetero-agglomerates are subsequently separated using a magnet. Five MP types (Polyethylene terephthalate (PET), polypropylene (PP), low density polyethylene (LDPE), polyvinyl chloride (PVC) and polystyrene (PS)) and cellulose particles were mixed in different combinations with both hydrophilic and hydrophobic (silanized) magnetite particles. PET, PP, LDPE and PS only poorly agglomerated with pristine (hydrophilic) magnetite, but efficiently formed hetero-agglomerates with hydrophobic magnetite and were successfully removed from suspensions ( $80 - 100 %$ ). PVC agglomerated more efficiently with pristine than with hydrophobic magnetite and cellulose only agglomerated to a limited extent with either hydrophilic or hydrophobic magnetite, resulting in a high process selectivity. Results from experiments conducted at different ionic strengths and with hydrophilic and hydrophobic magnetite suggests that the agglomeration process was dominated by hydrophobic interactions. Enzymatic and oxidative treatment of the MP only marginally affected the separation efficiencies and (treated) MP spiked to sewage sludge extracts were successfully recovered using magnetic seeded filtration.

Keywords: Cellulose; Environmental Samples; Extraction; Magnetic Separation; Microplastics; Sewage Sludge.