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Tier 2
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Original research — experimental, observational, or case-control study. Direct primary evidence.
Remediation
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An experimental and theoretical study of the erosion of semi-crystalline polymers and the subsequent generation of microparticles
Soft Matter2019
19 citations
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Citation count from OpenAlex, updated daily. May differ slightly from the publisher's own count.
Score: 30
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0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.
Researchers studied how semi-crystalline polymers erode and generate microparticles under physical and chemical stress, providing insight into how large plastic items break down in the environment. Understanding degradation kinetics is essential for predicting how microplastics accumulate over time.
The increase of plastics and microplastics in the environment is a major environmental challenge. Still, little is known about the degradation kinetics of macroplastics into smaller particles, under the joint actions of micro-organisms and physico-chemical factors, like UV or mechanical constraints. In order to gain insight into (bio)-degradation in various media, we perform accelerated erosion experiments by using a well-known enzymatic system. We show that the microstructure of semi-crystalline polymers plays a crucial role in the pattern formation at their surface. For the first time, the release of fragments of micrometric size is evidenced, through a mechanism that does not involve fracture propagation. A geometric erosion model allows a quantitative understanding of erosion rates and surface patterns, and provides a critical heterogeneity size, parting two types of behavior: spherulites either released, or eroded in situ. This new geometric approach could constitute a useful tool to predict the erosion kinetics and micro-particle generation in various media.