乙烯-辛烯均相共聚物的形貌。2退火后的结构变化

M. Peeters, B. Goderis, H. Reynaers, V. Mathot
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引用次数: 35

摘要

根据DSC证据,乙烯-1-辛烯共聚物的退火导致原始亚稳晶体的热稳定性逐渐提高。利用SAXS和WAXD监测在逐步升高的温度下等温退火固定时间后的结构变化。一系列不同摩尔质量和单体含量的样品,范围从0到11.8 mol % 1-辛烯,在150°C的两个极端速率下冷却,即淬火成液氮和以每分钟0.1°C的控制冷却到室温。在本研究中作为参考材料的淬火线型聚乙烯(LPEs)和1-辛烯含量为2.1 mol %的淬火共聚物的结晶度总是低于缓慢冷却样品的结晶度。另一方面,与缓慢冷却的样品相比,具有较高共聚物含量的淬火共聚物的结晶度更高。提出了一系列共结晶和再结晶事件来解释这一矛盾的,但可重复的实验事实。这一推理也可以解释后一种缓慢冷却的共聚物的非晶层厚度比淬火样品增加得更快的原因。所有共聚物在每个加热步骤后都表现出非常温和的层厚增加。除了额外结晶和再结晶外,晶体的横向生长和晶体密度的增加可以解释共聚物晶体在长时间退火过程中热稳定性的逐渐提高。观察到的lpe形态学效应证实了早期的发现。©1999 John Wiley & Sons, Inc[J] .高分子材料学报,2003,19 (3):559 - 561
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Morphology of homogeneous copolymers of ethylene and 1-octene. II. Structural changes on annealing
Based on DSC evidence, annealing of ethylene-1-octene copolymers results in a gradually increasing thermal stability of the original, metastable, crystals. SAXS and WAXD were used to monitor the structural changes involved after isothermal annealing for a fixed time at step-wise higher temperatures. A series of samples that differ in molar mass and comonomer content, ranging from 0 to 11.8 mol % 1-octene, were cooled at two extreme rates from 150°C, i.e., a quenching into liquid nitrogen and a controlled cooling at 0.1°C per minute to room temperature. The crystallinities of the quenched linear polyethylenes (LPEs), being included in this study as reference materials, and of the quenched copolymer with a 1-octene content of 2.1 mol % are always found to be lower than the crystallinities of the slowly cooled samples. On the other hand, higher crystallinities can be found for the quenched copolymers with a higher comonomer content compared to the slowly cooled specimens. A sequence of cocrystallization and recrystallization events is proposed to explain this contraintuitive, but reproducible experimental fact. This reasoning can also account for the steeper increase of the amorphous layer thickness of the latter slowly cooled copolymers compared to the quenched samples. All copolymers show a very moderate increase of the lamellar thickness after each heating step. Besides additional crystallization and recrystallization, lateral growth of the crystals and an increase of the crystallite density can account for the gradual increase of the thermal stability of copolymer crystals during prolonged annealing. The morphological effects observed for the LPEs confirm earlier findings. © 1999 John Wiley & Sons, Inc. J Polym Sci B: Polym Phys 37: 83–100, 1999
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来源期刊
CiteScore
5.90
自引率
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审稿时长
2.1 months
期刊介绍: Since its launch in 1946 by P. M. Doty, H. Mark, and C.C. Price, the Journal of Polymer Science has provided a continuous forum for the dissemination of thoroughly peer-reviewed, fundamental, international research into the preparation and properties of macromolecules. From January 2020, the Journal of Polymer Science, Part A: Polymer Chemistry and Journal of Polymer Science, Part B: Polymer Physics will be published as one journal, the Journal of Polymer Science. The merged journal will reflect the nature of today''s polymer science research, with physics and chemistry of polymer systems at the heart of the scope. You can continue looking forward to an exciting mix of comprehensive reviews, visionary insights, high-impact communications, and full papers that represent the rapid multidisciplinary developments in polymer science. Our editorial team consists of a mix of well-known academic editors and full-time professional editors who ensure fast, professional peer review of your contribution. After publication, our team will work to ensure that your paper receives the recognition it deserves by your peers and the broader scientific community.
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