Ethynyl‐terminated polyethers from new end‐capping agents. II. End‐chain functionalization through nitro displacement

Lucotte, Georges; Cormier, Laurent; Delfort, Bruno

doi:10.1002/pola.1991.080290615

Cited by 20 publications

(8 citation statements)

References 16 publications

(2 reference statements)

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“…Acetylene‐ or phenylacetylene‐terminated resins can be thermally cured without giving off volatiles. Acetylene groups have been used as crosslinking reaction sites in aromatic polyimides,1, 2 poly(ether ketone sulfone)s,3, 4 polyphenylquinoxalines,5 poly(phenyl‐ as ‐triazine)s,6 Schiff base polymers,7 poly(perfluoroalkylene ether benzoxazole)s,8 poly(phenylquinozaline)s9 and polyphenylenes 10. Resins terminated with acetylene or phenylacetylene have a long shelf life and their cured products have excellent solvent resistance and favorable combination of physical and mechanical properties at high temperature.…”

Section: Introductionmentioning

confidence: 99%

Synthesis and thermal cure of diphenyl ethers terminated with acetylene and phenylacetylene

Wang

Zhang

et al. 2006

Polymer International

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Two kinds of novel compounds, diphenylacetylene diphenyl ether (DPADPE) and diacetylene diphenyl ether (DADPE), were prepared and polymerized under heating. Raman, DSC and 13 C CP/MAS NMR analyses were used for studying the polymerization reaction. DPADPE and DADPE have melting points at 190 and 79 • C, with exothermic peaks of the DSC curves at 375 and 215 • C for curing, respectively. Raman and 13 C CP/MAS NMR spectra show that DPADPE could be cured at a temperature higher than 300 • C and DADPE at a lower temperature of higher than 150 • C. The kinetic parameters for the thermal crosslinking reactions were obtained by the Ozawa method and the results show that the apparent activation energy is 152 kJ mol −1 for DPADPE and 109 kJ mol −1 for DADPE. An ene-yne Straus product appears in the cured DADPE, whereas this product has not been identified in the cured DPADPE. The cured DPADPE and DADPE demonstrate good thermal and thermo-oxidative stability.

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Section: Introductionmentioning

confidence: 99%

Synthesis and thermal cure of diphenyl ethers terminated with acetylene and phenylacetylene

Wang

Zhang

et al. 2006

Polymer International

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“…DSC Characterization. The curing behavior of [1][2][3][4][5][6] was examined by DSC (Table 1). A DSC thermogram representative of these monomers is shown in Figure 2.…”

Section: Resultsmentioning

confidence: 99%

New High-Tg, Heat-Resistant, Cross-Linked Polymers. 2. Synthesis and Characterization of Polymers from Di-p-ethynyl-Substituted Benzyl Phenyl Ether Monomers

Melissaris¹,

Litt²

1994

Macromolecules

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Six different neat di-p-ethynylbenzyl phenyl ether (EBEs) monomers were thermally polymerized. The progress and nature of the polymerization reaction were studied by FTIR, Raman, and DSC. The monomers had melting points between 94 and 197 °C. FTIR, Raman, and DSC showed that the monomers polymerized to high conversion after heating to 290 °C at 15 °C/min (no remaining acetylenic groups). The monomer DSC thermograms showed two intense exotherms. The first was correlated with the thermal polymerization of the acetylenic groups to form a polyene structure with unusually high enthalpies of polymerization, between 106 and 178 kJ/mol. The second DSC exotherm enthalpies varied between 31 and 64 kJ/mol and are due to further coupling of the polyene chains. The cross-linked resins exhibited an initial decomposition temperature in nitrogen between 389 and 410 °C; they had a very high anaerobic char yield (61-71% at 800 °C). The benzyl phenyl ether link was found to be thermally and thermooxidatively stable in the cured polymers. This was attributed to their high cross-link density. Well-consolidated, voidfree films were obtained when the EBEs melt-polymerized. 4-Ethynyl-1-[ (4-ethynylphenyl)methoxy] benzene(1) and 2,5-bis[(4-ethynylphenyl)methoxy]toluene (4) had wide "processing windows" of 55 and 40 °C, respectively, at a heating rate of 15 °C/min (DSC). The polymers of 4 and l,4-bis[(4-ethynylphenyl)methoxy]-2-chlorobenzene (5) had Tg's of 364 and 330 °C, and their linear thermal expansions were 1.2 and 1% from room temperature to their Tg's. The cross-linked resins were amorphous. Their densities varied from 1.18 to 1.32 g/cm3.

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“…[14][15][16][17][18][19][20][21][22][23][24] The phenyl-ethynyl end-capped cured resins in general have shown improved thermooxidative stability and processability over thermally cured acetylene-terminated resins. [25][26][27][28][29] Our research program has built upon the NASA work and developed a variation of the phenyl-ethynyl end-capped oligomers that cure at significantly lower temperatures. 14,19,20 We found that by simply substituting the phenyl moiety with a naphthyl or anthracenyl ring a decrease in curing temperature of 30 and 80 °C, respectively, is observed.…”

Section: Introductionmentioning

confidence: 99%

“…In today's world of high energy costs and high tech applications, there continues to be a tremendous need and challenge for the development of lighter and yet mechanically more durable composite materials. One approach that has proven quite successful was initially developed by NASA involving the thermal cure of imide oligomers, which, after curing, affords a final resin with very desirable properties for use in high performance applications. − Others in the field have explored variations of the phenyl−ethynyl end-capped oligomers as well as probing the mechanism of the curing process(es). − The phenyl−ethynyl end-capped cured resins in general have shown improved thermooxidative stability and processability over thermally cured acetylene-terminated resins. − Our research program has built upon the NASA work and developed a variation of the phenyl−ethynyl end-capped oligomers that cure at significantly lower temperatures. ,, We found that by simply substituting the phenyl moiety with a naphthyl or anthracenyl ring a decrease in curing temperature of 30 and 80 °C, respectively, is observed.…”

Section: Introductionmentioning

confidence: 99%

Accelerated Curing of Aryl−Ethynyl End-Capped Polyimide Oligomers and Model Compounds: A Kinetic Study Probing Substituent Effects

2002

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phthalimide (1), N-phenyl-4-(4-methoxy-1-naphthylethynyl)phthalimide (2), and N-phenyl-4-(4-benzonitrileethynyl)phthalimide (3) were synthesized to probe the effect(s) of electronic subsituents on the thermal curing of aryl-ethynyl end-capped oligomers using end-cap model compounds. The curing kinetics were analyzed using SEC and NMR techniques and Arrhenius parameters were determined and compared to the anthracenyl, naphthyl, and phenyl analogues, 4, 5, and 6, respectively. A thermal curing rate acceleration was attributed to the electron-donating methoxy functionality. This acceleration is independent from the previously observed rate acceleration (phenyl < naphthyl < anthracenyl). Analyses of product distribution of 95% cured model compounds via SEC reveal slight differences between 1 and 4 but no discernible differences between 2 and 5. The incorporation of the electron-withdrawing group has no effect on the thermal cure rates, as the curing kinetics of 3 are nearly identical to those of 6. A new end-capping reagent, 4-(4methoxy-1-naphthylethynyl)phthalic anhydride ( 7) was synthesized and further used in the synthesis of 4-methoxynaphthylethynyl end-capped oligomer (4-MeO-NETI-5). By comparison to NETI-5, no significant changes are introduced by the methoxy-functionality except a reduction in thermal stability via SEC, DSC, and TGA. The curing kinetics of 4-MeO-NETI-5 were determined by monitoring the change in T g and analysis using the DiBenedetto equation. Unlike all analogous oligomers and model compounds including 2, a second-order rate law describes the curing kinetics of 4-MeO-NETI-5 better than a firstorder rate law. Arrhenius analysis of 4-MeO-NETI-5 using either a first-or second-order rate law results in indistinguishable Arrhenius parameters, and 4-MeO-NETI-5 cures with a lower Ea than NETI-5.

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Ethynyl‐terminated polyethers from new end‐capping agents. II. End‐chain functionalization through nitro displacement

Cited by 20 publications

References 16 publications

Synthesis and thermal cure of diphenyl ethers terminated with acetylene and phenylacetylene

Synthesis and thermal cure of diphenyl ethers terminated with acetylene and phenylacetylene

New High-Tg, Heat-Resistant, Cross-Linked Polymers. 2. Synthesis and Characterization of Polymers from Di-p-ethynyl-Substituted Benzyl Phenyl Ether Monomers

Accelerated Curing of Aryl−Ethynyl End-Capped Polyimide Oligomers and Model Compounds: A Kinetic Study Probing Substituent Effects

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