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In‐situ experimental study on the hydrolysis and pyrolysis processes of polylactic acid

Xia Zhao, Zhi Zheng, Jiangzhi Chen, Jianhui Sun, Mengjun Xiong, Xue Hou, Shenghua Mei

2024Polymer Engineering and Science14 citationsDOIOpen Access PDF

Abstract

Abstract In order to better understand the hydrolysis and pyrolysis process of polylactic acid (PLA), we carried out in‐situ experiments by observing the decomposition process of PLA at high temperature (up to 285°C) in both aqueous and anhydrous environments through fused silica capillary reactor (FSCR) combined with Raman spectroscopy analysis. By analyzing the strength change of characteristic peaks of PLA with increasing temperature, it was found that the initial melting temperature of PLA, in both the hydrolysis and pyrolysis processes, is around 170°C. Based on infrared spectroscopy analysis, it was found that the products of PLA pyrolysis are CO 2 , CH 3 CHCO, and CH 3 CHO, indicating that the pyrolysis process of PLA results from a free radical reaction. By comparing the Raman peak area ratios at different peak positions at different temperatures, it was found that the hydrolysis process of PLA mainly involves breaking the COC and CCO bonds of PLA, producing lactic acid, ethanol, CO 2 , and H 2 O. The hydrolysis reaction rate of PLA increases with the increase of temperature and exhibits a slow‐fast‐slow S ‐shaped trend. The kinetic process of hydrolysis of PLA was well described using the Logistic model. The activation energy for the hydrolysis ( Q ) of PLA is 18.1 kcal∙mol −1 in the temperature range of 250–285°C. The results of this study provide important insights and crucial parameters for the production and application of PLA.

Topics & Concepts

Polylactic acidHydrolysisRaman spectroscopyPyrolysisMaterials scienceDecompositionActivation energyLactic acidAqueous solutionAtmospheric temperature rangeAcid hydrolysisChemical engineeringOrganic chemistryChemistryComposite materialPolymerMeteorologyBiologyEngineeringPhysicsBacteriaGeneticsOpticsbiodegradable polymer synthesis and propertiesMicroplastics and Plastic PollutionRecycling and Waste Management Techniques