单体组分对萘基液晶聚芳酯纤维结构与性能的调控

doi:10.13475/j.fzxb.20250908201

Abstract

Abstract:

Objective To address the challenges of the narrow processing window and high melt viscosity associated with high-melting-point naphthalene-ring-based liquid crystal polyarylates, this study aimed to prepare a series of liquid crystal copolyester fibers with tunable thermal and mechanical properties by precisely adjusting the monomer ratio of 2,6-Naphthalenedicarboxylic acid (NDA) to terephthalic acid (TA). The goal was to elucidate the structure-property relationship, clarifying how monomer composition influences the molecular chain sequence structure and crystallization behavior, ultimately determining the final material performance.

Method A series of liquid crystal copolyesters derived from p-hydroxybenzoic acid (HBA), 2,6-naphthalenedicarboxylic acid (NDA), terephthalic acid (TA), and 4,4'-dihydroxybiphenyl (BP) were synthesized via melt polycondensation, producing nascent fibers. The molar ratio of NDA to TA was systematically varied, with the NDA content increasing from 7.5% to 20% and the TA content decreasing correspondingly from 17.5% to 5%, while keeping the total content of NDA and TA constant at 25 mol%. The contents of HNA and BP were fixed at 50% and 25%, respectively. The thermal properties, crystallization behavior, and mechanical properties of the resulting copolyesters were thoroughly characterized using differential scanning calorimetry (DSC), thermogravimetric analysis (TGA), X-ray diffraction (XRD), and a universal testing machine.

Results The results indicated that all copolyesters maintained similar lattice parameters (d=0.442-0.445 nm), suggesting an unchanged crystal structure. As the TA proportion increased, the melting temperature (T_m) of the copolyesters significantly decreased from 341 ℃ to 304 ℃, effectively broadening the processing window. Meanwhile, the char yield at 700 ℃ increased to 46.0%, demonstrating excellent thermal stability. The mechanical properties exhibited significant anisotropy, where the asymmetrically composed P-NDA10TA15 fiber achieved a tensile strength of 0.78 GPa, which was approximately 100% higher than that of the symmetrically composed P-NDA12.5TA12.5 (0.39 GPa). The high-TA-content fiber P-NDA7.5TA17.5 reached a modulus of 38.85 GPa. However, when the NDA content exceeded 17.5%, the crystallinity decreased drastically, leading to performance degradation. Rheological analysis confirmed the processing window was located in the viscous flow region (G″> G'), when G' and G″ represent the storage modulus and loss modulus, respectively, with the optimal spinning temperature not exceeding 390 ℃.

Conclusion The monomer composition is a crucial factor in regulating the hierarchical structure, thermal properties, and mechanical performance of liquid crystal polyarylates. Introducing TA units effectively modulates molecular chain packing and interactions, significantly lowering the melting temperature and broadening the processing window while maintaining the intrinsic high thermal stability of the material, thereby optimizing mechanical properties. The P-NDA10TA15 composition demonstrated the most balanced and superior overall performance. This research provides an effective strategy and a theoretical foundation for the molecular design of liquid crystal polyarylate fibers that combine excellent processability with high performance.

Key words: liquid crystal copolyester, naphthalene-ring polyacylates, melt polycondensation method, hierarchical structure, high-performance fiber, thermal property, mechanical property

CLC Number:

O632

ZHANG Jichao, LIU Yuchen, ZHANG Hao, GENG Jiajun, CAI Shuo, YANG Rumeng, LIU Ying, WEI Peng. Regulating monomer composition for structure and properties of naphthyl liquid crystalline polyarylate fiber[J].Journal of Textile Research, 2026, 47(02): 65-72.

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URL: http://www.fzxb.org.cn/EN/10.13475/j.fzxb.20250908201

http://www.fzxb.org.cn/EN/Y2026/V47/I02/65

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样品编号	HBA、NDA、TA、BP的量比
P-NDA7.5TA17.5	50∶7.5∶17.5∶25
P-NDA10TA15	50∶20∶15∶25
P-NDA12.5TA12.5	50∶12.5∶12.5∶25
P-NDA15TA10	50∶15∶10∶25
P-NDA17.5TA7.5	50∶17.5∶7.5∶25
P-NDA20TA5	50∶20∶5∶25

样品编号	T_g/℃	T_m/℃	T_c/℃	ΔH_m/ (J·g^-1)	ΔH_c/ (J·g^-1)
P-NDA7.5TA17.5	120	341	310	0.78	1.31
P-NDA10TA15	126	319	290	1.08	1.87
P-NDA12.5TA12.5	128	308	275	1.66	1.42
P-NDA15TA10	126	304	276	1.60	1.96
P-NDA17.5TA7.5	125	310	284	1.36	1.81
P-NDA20TA5	127	325	294	0.95	1.36

样品编号	T_5%/ ℃	T_10%/ ℃	T_20%/ ℃	T_dmax/ ℃	700 ℃时的残炭率/%
P-NDA7.5TA17.5	473	485	496	503	44.3
P-NDA10TA15	476	489	500	506	44.2
P-NDA12.5TA12.5	472	485	496	503	44.7
P-NDA15TA10	480	494	505	508	45.9
P-NDA17.5TA7.5	475	488	498	502	46.0
P-NDA20TA5	477	488	499	504	45.5

样品编号	2θ/(°)	d/nm	H/(°)	X_c/%
P-NDA7.5TA17.5	20.057	0.442 33	1.107	41.06
P-NDA10TA15	20.034	0.442 85	1.225	27.13
P-NDA12.5TA12.5	20.084	0.441 75	0.889	39.12
P-NDA15TA10	19.990	0.443 80	1.638	32.16
P-NDA17.5TA7.5	19.940	0.444 91	1.159	41.40
P-NDA20TA5	20.012	0.443 32	0.731	22.02

样品编号	断裂强度/ GPa	弹性模量/ GPa	断裂应变/ %
P-NDA7.5TA17.5	0.54 ± 0.07	38.85 ± 6.03	2.01 ± 0.26
P-NDA10TA15	0.78 ± 0.13	29.27 ± 3.41	1.46 ± 0.21
P-NDA12.5TA12.5	0.39 ± 0.05	33.21 ± 2.36	1.59 ± 0.25
P-NDA15TA10	0.42 ± 0.07	26.86 ± 3.60	1.95 ± 0.19
P-NDA17.5TA7.5	0.48 ± 0.06	30.83 ± 2.88	2.14 ± 0.26
P-NDA20TA5	0.21 ± 0.03	23.55 ± 2.17	1.14 ± 0.16

Regulating monomer composition for structure and properties of naphthyl liquid crystalline polyarylate fiber

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