生物基聚酯聚（2,5-呋喃乙烯酯）（PEF）的相图、玻璃态动力学和结晶动力学

IF 5.2 1区化学 Q1 POLYMER SCIENCE

Macromolecules Pub Date : 2024-10-04 DOI:10.1021/acs.macromol.4c01962

Ioannis Tzourtzouklis, Panagiotis Kardasis, George Z. Papageorgiou, George Floudas

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引用次数: 0

摘要

我们报告了生物基聚酯聚（2,5-呋喃乙酸乙烯酯）（PEF）的压力-温度（P-T）相图、亚玻璃动态的起源以及结晶动力学，测量结果与温度和压力有关。相图包括四个不同的 "相"：玻璃相、淬火熔体相、结晶相和正常熔体相。冷结晶温度 Tcc 随压力线性上升（根据克劳修斯-克拉皮隆方程），即 dTcc/dP|P→0 ∼ 240 K-GPa-1，同时伴随着比容的微小变化（ΔV = 0.028 cm3/g）。这与玻璃温度 Tg 更强的依赖性形成鲜明对比，后者的压力系数 dTg/dP|P→0 为 383 K-GPa-1，是刚性聚合物的典型特征。在压力的作用下，我们通过表观活化体积（只有通过压力实验才能获得的一个量）了解了亚玻璃 β 过程的分子起源。此外，增加压力会使分段过程变致密，但会阻碍 β 过程，这可能会对气体阻隔特性产生影响。通过热力学（差示扫描量热法，DSC）、动力学（DS）和结构（通过小角度（SAXS）和大角度（WAXS）同步 X 射线散射），按照相图中的不同路线，探索了从淬火熔体到冷结晶状态的结晶动力学。有趣的是，所有探针都遵循相同的西格码动力学（阿夫拉米类型），时间尺度相当。对等温结晶（Tc = 402 K；P = 0.1 MPa）过程中不同动态过程的介电强度演变进行检查后发现，在结晶的早期阶段不存在受限无定形部分（RAF）。这一观察结果与 G. Strobl 提出的介形相--结晶过程中在没有链折叠的情况下形成的中间相--相吻合。RAF 随后的生长遵循与热力学和结构探针所确定的相同的阿夫拉米动力学。P-T 相图中的浅层淬火确定了使 PEF 长期处于淬火非晶态的实验路线。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Phase Diagram, Glassy Dynamics and Crystallization Kinetics of the Biobased Polyester Poly(ethylene 2,5-furanoate) (PEF)

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Phase Diagram, Glassy Dynamics and Crystallization Kinetics of the Biobased Polyester Poly(ethylene 2,5-furanoate) (PEF)

We report the pressure–temperature (P–T) phase diagram, the origin of the subglass dynamics, and the crystallization kinetics of the biobased polyester poly(ethylene 2,5-furanoate) (PEF), through dielectric spectroscopy (DS) measurements performed as a function of temperature and pressure. The phase diagram comprises four different “phases”; glass, quenched melt, crystalline, and normal melt. The cold crystallization temperature, T_cc, increases linearly with pressure (according to the Clausius–Clapeyron equation) as dT_cc/dP_|_P_→0 ∼ 240 K·GPa^–1 and is accompanied by a small change in specific volume (ΔV = 0.028 cm³/g). This contrasts with the stronger dependence of the glass temperature, T_g, with a pressure coefficient, dT_g/dP_|_P_→0, of 383 K·GPa^–1, typical of rigid polymers. With the application of pressure, we address the molecular origin of the subglass β-process through the apparent activation volume, a quantity accessible only by pressure experiments. Moreover, increasing pressure densifies the segmental process but blocks the β-process, with possible implications in the gas-barrier properties. The crystallization kinetics from the quenched melt to the cold-crystallized state was explored by thermodynamics (differential scanning calorimetry, DSC), dynamics (DS), and structure (via simultaneous X-ray scattering at small (SAXS) and wide (WAXS) angles) following different routes within the phase diagram. Interestingly, all probes followed the same sigmoidal kinetics (of the Avrami type) with comparable time scales. Inspection of the evolution of the dielectric strength for the different dynamic processes during isothermal crystallization (at T_c = 402 K; P = 0.1 MPa) revealed the absence of the restricted amorphous fraction (RAF) at the early stages of crystallization. This observation is in line with the proposed mesomorphic phase─an intermediate phase formed during crystallization in the absence of chain folding, as suggested by G. Strobl. Subsequent growth of the RAF followed the same Avrami kinetics as identified by the thermodynamic and structural probes. Shallow quenches within the P–T phase diagram identified experimental routes for keeping PEF in the metastable quenched amorphous state for long times.

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来源期刊

Macromolecules 工程技术-高分子科学

CiteScore

9.30

自引率

16.40%

发文量

942

审稿时长

2 months

期刊介绍： Macromolecules publishes original, fundamental, and impactful research on all aspects of polymer science. Topics of interest include synthesis (e.g., controlled polymerizations, polymerization catalysis, post polymerization modification, new monomer structures and polymer architectures, and polymerization mechanisms/kinetics analysis); phase behavior, thermodynamics, dynamic, and ordering/disordering phenomena (e.g., self-assembly, gelation, crystallization, solution/melt/solid-state characteristics); structure and properties (e.g., mechanical and rheological properties, surface/interfacial characteristics, electronic and transport properties); new state of the art characterization (e.g., spectroscopy, scattering, microscopy, rheology), simulation (e.g., Monte Carlo, molecular dynamics, multi-scale/coarse-grained modeling), and theoretical methods. Renewable/sustainable polymers, polymer networks, responsive polymers, electro-, magneto- and opto-active macromolecules, inorganic polymers, charge-transporting polymers (ion-containing, semiconducting, and conducting), nanostructured polymers, and polymer composites are also of interest. Typical papers published in Macromolecules showcase important and innovative concepts, experimental methods/observations, and theoretical/computational approaches that demonstrate a fundamental advance in the understanding of polymers.