Atomic oxygen erosion of a poly(ester-imide) film

IF 7.4 2区化学 Q1 POLYMER SCIENCE Polymer Degradation and Stability Pub Date : 2025-02-01 DOI:10.1016/j.polymdegradstab.2024.111137

Yifan Zhang , Shengqi Dai , Pan Pang , Xiaoyue Jin , Qian Li , Lin Chen , Bin Liao

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Abstract

Poly(ester-imide)s (PEIs) are considered the most promising polymers for space exploration attributed to their flexibility, low-density, and outstanding mechanical behaviors. Nevertheless, their atomic oxygen (AO) degradation effects pose a significant challenge for PEI films deployed in low Earth orbit (LEO). In this study, we examined the structural evolution behaviors and AO degradation mechanisms of the PEI by integrating exposure tests with reactive molecular dynamics (ReaxFF-MD) simulation. The PEI exhibited linear AO erosion kinetics, characterized by a constant erosion yield (E_y) of ∼1.1 × 10⁻²⁴ cm³ atom⁻¹. Morphological analysis revealed the ascending surface roughnesses and shaggy topographies as AO fluence increased. Spectroscopic investigations demonstrated that the extensive elimination of specific sites (C=O, C-O-C, C-N, C-H, and C-C groups) and the release of volatile species (H₂O, CO_x, and NO_x) were the priority consequences of AO erosion. In addition, the AO-exposed PEI demonstrated the gradual declines in hydrophobicity and transparency. Moreover, the ReaxFF-MD simulation aligned with the experimental results, further corroborating the rationality of the collision enhanced erosion reaction mechanism.

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聚酯-酰亚胺薄膜的原子氧侵蚀

聚酰亚胺（PEIs）由于其柔韧性、低密度和优异的力学性能，被认为是空间探索中最有前途的聚合物。然而，它们的原子氧（AO）降解效应对在低地球轨道（LEO）上部署PEI薄膜提出了重大挑战。本研究采用暴露试验与反应分子动力学（ReaxFF-MD）模拟相结合的方法，研究了PEI的结构演化行为和AO降解机制。PEI表现出线性AO侵蚀动力学，其特征是恒定的侵蚀产率（Ey）为~ 1.1 × 10−24 cm3原子−1。形态学分析表明，随着AO浓度的增加，表面粗糙度上升，地形粗糙。光谱研究表明，特定位点（C=O、C-O-C、C- n、C- h和C-C基团）的广泛消除和挥发性物质（H2O、COx和NOx）的释放是AO侵蚀的首要后果。此外，ao暴露PEI的疏水性和透明度逐渐下降。ReaxFF-MD模拟与实验结果吻合，进一步证实了碰撞增强冲蚀反应机理的合理性。

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来源期刊

Polymer Degradation and Stability 化学-高分子科学

CiteScore

10.10

自引率

10.20%

发文量

325

审稿时长

23 days

期刊介绍： Polymer Degradation and Stability deals with the degradation reactions and their control which are a major preoccupation of practitioners of the many and diverse aspects of modern polymer technology. Deteriorative reactions occur during processing, when polymers are subjected to heat, oxygen and mechanical stress, and during the useful life of the materials when oxygen and sunlight are the most important degradative agencies. In more specialised applications, degradation may be induced by high energy radiation, ozone, atmospheric pollutants, mechanical stress, biological action, hydrolysis and many other influences. The mechanisms of these reactions and stabilisation processes must be understood if the technology and application of polymers are to continue to advance. The reporting of investigations of this kind is therefore a major function of this journal. However there are also new developments in polymer technology in which degradation processes find positive applications. For example, photodegradable plastics are now available, the recycling of polymeric products will become increasingly important, degradation and combustion studies are involved in the definition of the fire hazards which are associated with polymeric materials and the microelectronics industry is vitally dependent upon polymer degradation in the manufacture of its circuitry. Polymer properties may also be improved by processes like curing and grafting, the chemistry of which can be closely related to that which causes physical deterioration in other circumstances.