The mechanical properties of thermally treated 73/27 HBA/HNA copolyester

Kim, Youn Cheol; Economy, James

doi:10.1002/(sici)1099-1581(199908)10:8<493::aid-pat883>3.0.co;2-j

Cited by 4 publications

(2 citation statements)

References 16 publications

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“…In general, polymers with higher crystallinity and better chain alignment tend to have larger thermal conductivities. ,, The low thermal conductivity of Vectra is probably attributable the disorder in the chain segments; the relatively low crystallinity of ∼20% as reported in ref may also contribute to the low thermal conductivity. For LCP fibers with various chemical structures as depicted in Figure , the increase in the number of side chains in each molecular unit is likely to reduce the axial conductivity due to additional phonon scattering created by the vibrational modes of the side chains.…”

Section: Results and Discussionmentioning

confidence: 88%

Thermal Conductivity of High-Modulus Polymer Fibers

et al. 2013

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Polymers have many desirable properties for engineering systems−e.g., low mass density, chemical stability, and high strength-to-mass ratio−but applications of polymers in situations where heat transfer is critical are often limited by low thermal conductivity. Here, we leverage the enormous research and development efforts that have been invested in the production of high-modulus polymer fibers to advance understanding of the mechanisms for thermal transport in this class of materials. Time-domain thermoreflectance (TDTR) enables direct measurements of the axial thermal conductivity of a single polymer fiber over a wide temperature range, 80 < T < 600 K. Relaxation of thermoelastic stress in the Al film transducer has to be taken into account in the analysis of the TDTR data when the laser spot size is small because the radial modulus of the fiber is small. This stress relaxation is controlled by the velocity of the zero-order symmetric Lamb mode of a thin Al plate. We find similarly high thermal conductivities of Λ ≈ 20 W m −1 K −1 in crystalline polyethylene and liquid crystalline poly(p-phenylene benzobisoxazole). For both fiber types, Λ(T) ∝ 1/T near room temperature, suggesting an intrinsic limit to the thermal conductivity governed by anharmonicity, not structural disorder. Because of the high degree of elastic anisotropy, longitudinal acoustic phonons with group velocities directed along fiber axis are likely to be the dominate carriers of heat.

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Section: Results and Discussionmentioning

confidence: 88%

Thermal Conductivity of High-Modulus Polymer Fibers

et al. 2013

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“…One of the most commercially successful TLCPs, known as Vectra, is also a series of random copolymers synthesized from ≈75 mol% HBA and ≈25 mol% HNA monomers. [ 18–20 ] The naphthalene linkage derived from HNA monomer acts as a crankshaft, reducing the regularity of the main chain and the melting points of HBA‐based TLCPs. On the contrary, TLCPs incur high production costs primarily due to the costly monomer, HNA.…”

Section: Introductionmentioning

confidence: 99%

Effects of Para‐ or Meta‐Aromatic Amide Units on the Microstructure, Thermal, Mechanical, Rheological, and Dielectric Properties of Thermotropic Liquid Crystalline Poly(ester amide)s

Song,

Park,

Tang

et al. 2023

Macro Chemistry & Physics

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The impact of para‐ and meta‐aromatic amide repeat units on the microstructure, thermal behavior, mechanical properties, rheological characteristics, and dielectric properties of thermotropic liquid crystalline poly(ester amide)s (TPEAs) is reported. For this purpose, two distinct series of TPEAs are synthesized using 75.0 mol% of 4‐hydroxybenzoic acid (HBA) and 25.0–17.5 mol% of 6‐hydroxy‐2‐naphtoic acid (HNA) with 0.0–7.5 mol% terephthalic acid/para‐acetylaminophenol (TPA/PAP) or isophthalic acid/para‐acetylaminophenol (IPA/PAP) are synthesized via bulk polycondensation reaction. Infrared and electron microscopic data reveal the existence of intermolecular hydrogen bonds and associated fibrillar structures of TPEAs with TPA/PAP‐ or IPA/PAP‐based aromatic amide units. Accordingly, the glass transition temperatures, dynamic storage moduli, and melt viscosities of TPEAs increased with the increment of the aromatic amide units, although they are higher for TPEAs with IPA/PAP‐derived units, compared to TPEAs with TPA/PAP‐derived units. The melting temperatures of TPEAs increase with the para‐aromatic amide unit owing to the intermolecular hydrogen bonding and the rigid linearity, whereas the melting points decrease with the meta‐aromatic amide unit due to the structural nonlinearity. Interestingly, the dielectric constants and losses of TPEAs decrease with the aromatic amide unit content, which is even dominant for TPEAs with IPA/PAP‐based repeat units. TPEAs can be thus utilized as super‐engineering plastics, industrial fibers, printed circuit board materials, etc., requiring enhanced mechanical and thermal transition properties but lower dielectric constants and losses.

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