Crystallization Behavior of Rapid-Compression-Induced Mesomorphic Isotactic Polypropylene during Uniaxial Stretching at Different Temperatures

IF 1.9 Q2 CRYSTALLOGRAPHY

Polymer Crystallization Pub Date : 2022-05-26 DOI:10.1155/2022/5750961

Ming-fei Xu, Jiaxiang Lin, Xiaolin Zhang, Zhenyin Li, Chuntai Liu, Changyu Shen, Chunguang Shao

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引用次数: 1

Abstract

The uniform bulk mesomorphic iPP is prepared by rapid compression, and its structural evolution under stretching at different temperatures is studied by combining wide-angle X-ray diffraction and small-angle X-ray scattering. Results show that stretching can induce mesophase to crystallize into α-phase or promote this phase transformation synergistically with temperature, which depends on the selection of stretching temperature. When the temperature is lower than the glass transition temperature of rigid amorphous fraction (RAF), stress could make RAF devitrify firstly and then induce meso-α phase transition during the strain-softening process. As the temperature increases, the high temperature could induce meso-α phase transition to occur before the strain softening, while stretching could promote this transition. When the temperature is higher than a critical value around 100°C, the mesophase can be transformed into α-phase completely during stretching. SAXS results show that all the transformed α-crystal exhibits nodular morphology, and they are ductile with greatly enhanced deformability. Based on the results, a reasonable mechanism of meso-α transformation in the stretching process is proposed, explaining the phase transition that goes through several different steps.

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不同温度下快速压缩诱导的中晶等规聚丙烯单轴拉伸结晶行为

采用快速压缩法制备了均匀体亚晶iPP，并结合广角x射线衍射和小角x射线散射研究了其在不同温度下拉伸的结构演变。结果表明，拉伸可以诱导中间相向α-相结晶或与温度协同促进α-相的转变，具体取决于拉伸温度的选择。当温度低于刚性非晶部分(RAF)的玻璃化转变温度时，应力会使RAF先失氮化，然后在应变软化过程中诱发介观α相变。随着温度的升高，高温可以在应变软化前诱发介观α相变，而拉伸可以促进这一转变。当温度高于100℃左右的临界值时，中间相在拉伸过程中完全转变为α-相。SAXS结果表明，转变后的α-晶体均呈现出结节状形态，具有良好的延展性，变形能力大大增强。在此基础上，提出了拉伸过程中介观α转变的合理机理，解释了拉伸过程中几个不同阶段的相变。

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来源期刊

Polymer Crystallization Materials Science-Materials Science (miscellaneous)

CiteScore

4.70

自引率

0.00%

发文量