Experimental Validation of the Microplastic Index—Two Approaches to Understanding Microplastic Formation

Microplastics and nanoplastics Pub Date : 2023-11-03 DOI:10.3390/microplastics2040027

Kalouda Grigoriadi, Merel G. A. Nooijens, Ali Emre Taşli, Max M. C. Vanhouttem, Sieger Henke, Luke A. Parker, Jan Harm Urbanus, Arjen Boersma

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Abstract

The Microplastic Index (MPI) was presented in a previous paper as a method to assess the formation of microplastics during the application of impact and wear stresses, based on selected mechanical and physical properties of polymers. In this paper, the experimental validation of the MPI model is presented. A series of ten polymers was characterized to obtain the relevant parameters for the calculation of the MPI, i.e., the minimum particle size and volume of microplastics formed. The milling (addressing impact stress) and sanding experiments (addressing wear stress) resulted in particle sizes between 3 and 200 μm and 0.3 and 25 μm, respectively. These values were very well predicted by the MPI model, showing smaller particles for brittle polymers and larger ones for ductile polymers. In addition, the experimental-specific wear rates of impact and wear correlated well with the predicted ones, being 0.01–30 mm3/Nm for impact and 0.0002–0.012 mm3/Nm for wear. These results indicate that the MPI can be very well used to predict the tendency of a material to form microplastics. In the search for understanding and mitigating microplastic formation, the MPI can be used by both producers and end users to choose plastic grades that form fewer microplastics.

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微塑性指数的实验验证——理解微塑性形成的两种方法

微塑性指数(MPI)在之前的一篇论文中提出，是一种基于聚合物的选定机械和物理性能，评估在冲击和磨损应力作用下微塑料形成的方法。本文对MPI模型进行了实验验证。对10种聚合物进行了表征，得到了计算MPI的相关参数，即形成的微塑料的最小粒径和体积。铣削(处理冲击应力)和砂磨(处理磨损应力)实验的结果表明，颗粒尺寸分别在3 ~ 200 μm和0.3 ~ 25 μm之间。MPI模型很好地预测了这些值，表明脆性聚合物的颗粒较小，而韧性聚合物的颗粒较大。此外，冲击和磨损的实验特定磨损率与预测值相关性较好，冲击和磨损的实验特定磨损率分别为0.01 ~ 30 mm3/Nm和0.0002 ~ 0.012 mm3/Nm。这些结果表明，MPI可以很好地用于预测材料形成微塑料的趋势。为了了解和减少微塑料的形成，生产商和最终用户都可以使用MPI来选择形成较少微塑料的塑料等级。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Microplastics and nanoplastics

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