Characterization of Potential Pollutants from Poly(lactic acid) after the Degradation Process in Soil under Simulated Environmental Conditions

AppliedChem Pub Date : 2021-12-10 DOI:10.3390/appliedchem1020012

Marta Krawczyk-Walach, K. Gzyra-Jagieła, A. Milczarek, Jagoda Jóźwik-Pruska

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引用次数: 2

Abstract

In recent years, the amount of produced petrochemical plastic waste has been growing at an alarming rate. According to the Plastics Europe Market Research Group (PEMRG)/Conversio Market & Strategy GmbH, in 2018 the global production of plastics amounts to 359 million tons, and in Europe—61.8 million tons. More than 80% of all marine litter is plastic, which accumulates in the environment due to its durability. Due to the growing problem, biodegradable polymer products are introduced to the market. Therefore, it is necessary to conduct research on degradation products in order to estimate the risk arising from their presence in the environment. This paper discusses research on compounds that may potentially remain in the soil after the degradation of the double green PLA polymer. The aim of the research was to prove whether products made of PLA, e.g., packaging, films and other waste can release substances harmful to the environment. Therefore, soil was selected as a medium to characterize the substances potentially released from the polymer under conditions simulating the degradation process in the environment. The soil was always used from the same producer. Before the polymer biodegradation process, it was additionally checked for pH, C and N content, number of microorganisms, etc. PLA degradation in soil was carried out in a laboratory accredited by the Polish Accreditation Center (PCA). During the research, soil samples at various stages of the degradation process under laboratory conditions were subjected to both extraction in an aqueous environment and organic solvent extraction The studies used the gas chromatography coupled with mass spectrometry (GC/MS), as well as pyrolysis gas chromatography (Py-GC/MS). In addition, the study used the gel permeation chromatography (GPC/SEC) allowing to determine the distribution of molar masses, average molar masses and polydispersity, and the infrared spectroscopy (FTIR).

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模拟环境条件下聚乳酸在土壤中降解过程中潜在污染物的表征

近年来，石化塑料废弃物产生量以惊人的速度增长。根据欧洲塑料市场研究集团(PEMRG)/ convert Market & Strategy GmbH的数据，2018年全球塑料产量为3.59亿吨，欧洲为6180万吨。超过80%的海洋垃圾是塑料，由于其耐久性而在环境中积累。由于这一日益严重的问题，可生物降解聚合物产品被引入市场。因此，有必要对降解产物进行研究，以估计其在环境中的存在所带来的风险。本文对双绿聚乳酸降解后可能残留在土壤中的化合物进行了研究。研究的目的是证明PLA制成的产品，如包装，薄膜和其他废物是否会释放对环境有害的物质。因此，选择土壤作为介质来表征在模拟环境降解过程的条件下聚合物可能释放的物质。土壤总是来自同一个生产者。在聚合物生物降解前，还对其进行了pH、C、N含量、微生物数量等检测。PLA在土壤中的降解在波兰认证中心(PCA)认可的实验室进行。在研究过程中，在实验室条件下，对处于降解过程不同阶段的土壤样品进行了水萃取和有机溶剂萃取，研究采用了气相色谱-质谱联用(GC/MS)和热解气相色谱联用(Py-GC/MS)。此外，采用凝胶渗透色谱法(GPC/SEC)测定了样品的摩尔质量、平均摩尔质量和多分散性的分布，并采用红外光谱法(FTIR)进行了分析。

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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AppliedChem

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