Melt processable homo- and copolyimides with high thermo-oxidative stability as derived from mixed thioetherdiphthalic anhydride isomers

Han, Yanchun; Xz, Fang; Xx, Zuo

doi:10.3144/expresspolymlett.2010.86

Cited by 19 publications

(17 citation statements)

References 21 publications

(36 reference statements)

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“…The PIHSTs prepared with copolyimides of 6FDA/ODA + BAB are labeled as PIHST04, PIHST05, PIHST06, PIHST07 and PIHST08, whose molar ratios of ODA:BAB were 0.15:0.85, 0.30:0.70, 0.50:0.50, 0.70:0.30 and 0.88:0.12, respectively. Just like other copolyimides reported, the m/n ratios of ODA:BAB for the shape memory copolyimides are also similar to the specific molar ratios in the synthesis process, as the reactant monomers are not detected in the products44454647.…”

Section: Resultssupporting

confidence: 75%

Rigid High Temperature Heat-Shrinkable Polyimide Tubes with Functionality as Reducer Couplings

Kong

Xiao

2017

Sci Rep

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Flexible and semi-rigid heat-shrinkable tubes (HSTs) have been used in thousands of applications, and here rigid high temperature HSTs are reported for the first time. These rigid HSTs are prepared with shape memory polyimides possessing glass transition temperatures (Tgs) from 182 to 295 °C, and the relationships between Tg and their molecular structures are studied. The polyimide HSTs (PIHSTs) can fix expanded diameters and shrink back to original diameters very well, and the mechanisms of their heat-shrinkage performance are discussed. Their differences from commercially available HSTs in heat-shrinkage are also analyzed. They can withstand low temperature of −196 °C, much lower than those of other HSTs. The PIHSTs can also connect subjects of different sizes by heat-shrinkage and then fix them upon cooling like reducer couplings, and the possible mechanisms of their reducer coupling effect are analyzed. With their unique characteristics, PIHSTs will expand the application areas of HSTs enormously.

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Section: Resultssupporting

confidence: 75%

Rigid High Temperature Heat-Shrinkable Polyimide Tubes with Functionality as Reducer Couplings

Kong

Xiao

2017

Sci Rep

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“…The asymmetrical structure of 3,4 0 -TDPA and 3,3 0 -TDPA in the polymer backbones could dramatically reduce the polymer chain-to-chain interactions. 29,34,35 Furthermore, decreasing the molecular weights of the oligomers led to an apparent drop in the minimum melt viscosity, and at the same time, it provided a broader processing window as expected. 17,26,33 Isothermal viscosity measurements at 280 C were also conducted to test the melt stability.…”

Section: Melt Processability Of Phenylethynly-terminated Oligomersmentioning

confidence: 57%

Phenylethynyl-terminated imide oligomers derived from thioetherdiphthalic anhydride isomers with decreased melt viscosities

Sun

Wang

et al. 2016

High Performance Polymers

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A series of oligomers based on the mixture of thioetherdiphthalic anhydride isomers and 4,4 0 -oxydianiline with 4-phenylethynylphthalic anhydride as reactive endcapping reagent were prepared. The calculated molecular weights were in the range of 1150-5070 g mol À1 with different degrees of polymerization (n ¼ 1, 3, 5, 7, and 9). The effect of molecular weight of the aromatic oligomers on their processability and solubility as well as the thermal and mechanical properties of the thermal-cured polyimides (PIs) was systematically investigated. The typical oligomer (Oligo-1) could be melted at temperatures of 289-334 C to yield stable molten fluid with melt viscosity below 1.0 Pa s. The melt viscosity of the oligomers increased with the increasing molecular weight. After thermally curing at 370 C, the thermoset PIs exhibited good thermal properties. The glass transition temperatures of oligomers measured by differential scanning calorimetry were in the range of 286-326 C, and the temperature of 5% weight loss was higher than 524 C. The cured films also showed good mechanical properties with tensile strength above 72 MPa and modulus more than 2.5 GPa.

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“…It has been proved that the fitting of T g s to Fox Equation is mainly caused by the similarity in molecular structures of polymer components of the copolymers . As manifested in Figure , both BAB and BAPB molecules contain two ether linkages connecting benzene rings, and thus there is similarity in the molecular structures of BPADA/BAB and BPADA/BAPB.…”

Section: Resultsmentioning

confidence: 97%

“…Copolymerization is an efficient and convenient method to obtain polymers with expected properties, and copolyimides have attracted attentions from various fields . The shape memory copolyimides of BPADA/BAB‐BAPB were synthesized with two‐step polycondensation process by employing BPADA as dianhydride and the combination of BAB and BAPB as diamines, and the sythesis process is shown in Figure .…”

Section: Resultsmentioning

confidence: 99%

Facile control of high temperature shape memory polymers

Qiu

Xiao

Kong

et al. 2017

J of Applied Polymer Sci

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Glass transition temperature (Tg) is crucial in determining application areas of high temperature shape memory polymers (SMPs), but some Tgs are difficult or uneconomic to be obtained. Here we introduce a facile way to prepare high temperature SMPs with controllable Tgs from 183 to 230 °C by copolymerization of polyimides, and relationships between Tgs and diamine components of the shape memory copolyimides agree with Fox Equation. These copolyimides can fix temporary shape and return to original shape nicely, and the possible mechanisms of their high shape fixity and shape recovery are analyzed on the basis of thermomechanical properties and molecular structures. The copolymerization of shape memory polyimides has offered an effective way to obtain high temperature SMPs with desired properties. © 2017 Wiley Periodicals, Inc. J. Appl. Polym. Sci. 2017, 134, 44902.

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Melt processable homo- and copolyimides with high thermo-oxidative stability as derived from mixed thioetherdiphthalic anhydride isomers

Cited by 19 publications

References 21 publications

Rigid High Temperature Heat-Shrinkable Polyimide Tubes with Functionality as Reducer Couplings

Rigid High Temperature Heat-Shrinkable Polyimide Tubes with Functionality as Reducer Couplings

Phenylethynyl-terminated imide oligomers derived from thioetherdiphthalic anhydride isomers with decreased melt viscosities

Facile control of high temperature shape memory polymers

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