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Development of Polyolefin Elastomers with Distinct Dual Long-Chain Branch Structures

Bangban Zhu, Haitao Wang, Kan Liu, Minghao Sun, Zhenjia Shi, Shuo Wang, Xingfen Huang, Shengbin Shi, Jieyuan Zheng, Xuan Yang, Pingwei Liu, Wenjun Wang

2025Macromolecules8 citationsDOI

Abstract

Long-chain branched (LCB) structures significantly impact the processability and mechanical performance of polyolefin materials. Comb-branched polyolefin elastomer (CPOE) represents an emerging class of polyolefin thermoplastic elastomers composed of an amorphous ethylene/1-octene copolymer backbone and crystalline polyethylene (PE) LCBs (T-type). While CPOEs exhibit higher melting points and improved thermal stability compared to conventional polyolefin elastomers, achieving both high mechanical strength and excellent elastic recovery remains a key challenge. In this study, a second LCB structure was strategically introduced into CPOEs to develop a dual-branched polyolefin elastomer (DPOE). In addition to the existing crystalline T-type LCBs, which act as reversible physical cross-linking sites, covalently bonded H-type LCBs were generated through the incorporation of 1,7-octadiene. The resulting DPOEs possessed 0.5–0.6 T-type LCBs and 0.5–1.6 H-type LCBs per polymer chain, forming an integrated dual cross-linking network. This dual-LCB design led to a remarkable enhancement in mechanical properties and thermal performance. Compared to CPOEs, the DPOEs exhibited an increase in tensile strengths from 9.4 to 16.6 MPa, elongations at break from 975% to 1085%, toughness from 70.1 MJ/m 3 to 105 MJ/m 3, and elastic recoveries from 65.8% to 73.7%. Furthermore, the DPOEs maintained a storage modulus plateau of 0.2–0.3 MPa across the 150–200 °C range. Notably, the materials also showed outstanding reprocessability, retaining up to 96% of their original mechanical strengths and nearly unchanged elongations at break after five hot-pressing cycles. The introduction of dual LCBs offers a powerful design strategy for producing high-performance, thermally stable, and reprocessable polyolefin thermoplastic elastomers, expanding their potential for advanced industrial applications.

Topics & Concepts

PolyolefinMaterials scienceElastomerThermoplastic elastomerComposite materialToughnessThermoplasticUltimate tensile strengthCrystallinityPolyethylenePolymerThermal stabilityCopolymerElastic modulusNatural rubberModulusDynamic mechanical analysisSynthetic fiberAmorphous solidYoung's modulusIzod impact strength testMelt flow indexPolymer scienceEmbrittlementPolymer crystallization and propertiesAdvanced Polymer Synthesis and CharacterizationPolymer Nanocomposites and Properties
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