Influence of Ethylene-1-Alkene Copolymers Microstructure on Thermo-Rheological Behavior of Model Blends for Enhanced Recycling

Macromol Pub Date : 2022-04-24 DOI:10.3390/macromol2020011

G. Galgali, S. Kaliappan, Tej Pandit

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引用次数: 1

Abstract

Polyethylenes (PE) are the most commonly occurring ingredients for post-consumer recyclates (PCR). The structure–property relationships of different types of model PE-based blends are established using multiple thermo-rheological analyses. Although considered “simple”, the complex behavior of model PE-based blends is experimentally demonstrated for the first time for metallocene-catalyzed, linear, low-density polyethylenes (mLLDPE) with different microstructures that are commonly encountered in PCR. During non-isothermal crystallization, the microstructure of mLLDPE predominantly influences the interaction between mLLDPE and LDPE. Based on the mLLDPE microstructure, the molten LDPE phase acts either as a nucleating agent or as a crystallization rate promoting agent. Both rheological and thermal analyses show that higher activation energy is required for the reptation or movement of polymer chains in a highly branched microstructure with long chain branching (LCB) compared to a linear microstructure with short chain branching (SCB). The quasi-melt response, as measured by thermal analysis under non-isothermal conditions, is distinctly different and sensitive to both the SCB and LCB present in the LLDPE/LDPE blends.

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乙烯-1-烯烃共聚物微观结构对模型共混物热流变行为的影响

聚乙烯(PE)是消费后回收(PCR)中最常见的成分。通过多次热流变分析，建立了不同类型聚乙烯基模型共混物的结构-性能关系。虽然被认为是“简单的”，但模型聚乙烯基共混物的复杂行为首次在实验中被证明是由茂金属催化的、具有不同微观结构的线性低密度聚乙烯(mLLDPE)，这些聚乙烯在PCR中经常遇到。在非等温结晶过程中，mLLDPE的微观结构主要影响mLLDPE与LDPE的相互作用。根据mLLDPE的微观结构，熔融LDPE相既可以作为成核剂，也可以作为结晶速率促进剂。流变学和热分析表明，与具有短链分支(SCB)的线性结构相比，具有长链分支(LCB)的高支化结构中聚合物链的重复或运动需要更高的活化能。非等温条件下的热分析表明，LLDPE/LDPE共混物的准熔体响应明显不同，对SCB和LCB都很敏感。

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来源期刊

Macromol

CiteScore

5.20

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0.00%

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