Preparation, characterization, and porperties of optically active poly(α‐methyl‐α‐ethyl‐β‐propiolactones)

Grenier, Daniel; Prud’homme, Robert E.; Leborgne, Alain; Spassky, Nicolas

doi:10.1002/pol.1981.170190717

Cited by 29 publications

(18 citation statements)

References 40 publications

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“…The stereocomplex melted at a temperature 50 degrees higher than that of the a-form. Similar behavior has been reported by Prud'homme et al [1][2][3][4][5][6] for the optically active forms of poly(a-methyl-a-ethyl-/3-propiolactone).…”

Section: Introductionsupporting

confidence: 87%

“…Table 1 contains the estimates of the parameters Go, U*, Kgt and ooe that result from the best fit of the data to the growth rate equation (1) by the procedures described previously.39 The pre-exponential parameter, Go, may be the most poorly defined parameter of the growth rate equation, mainly due to a general lack of growth rate data for polymers at large undercoolings. The observed differences in the estimates of Go reported in Table 1 are relatively small, as might be expected for similar polymers.…”

Section: Tc(adfmentioning

confidence: 99%

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Optically Active Polyethers. 1. Studies of the Crystallization in Blends of the Enantiomers and the Stereoblock Form of Poly(epichlorohydrin)

Singfield¹,

Brown²

1995

Macromolecules

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The isothermal crystallization kinetics and morphology of the melt-crystallized optically active polyenantiomers, their blends, and the stereoblock form of poly(epichlorohydrin) have been investigated using polarized light video microscopy. The optically active polyenantiomers develop regularly banded spherulites, while the equimolar blend and the stereoblock polymer form nonbanded, coarser spherulites. The apparent morphological differences among the polymers suggest a stereospecific segregation at the growth front in an attempt to produce optically pure lamellae. The equilibrium melting temperature as determined by the classical Hoffman-Weeks method was found to be 411 ± 1 K for all of the polymers. Over the range of crystallization temperatures from the Tt (247 K) to Tm°, the spherulite radial growth rates of the 50:50 blend of the polyenantiomers are depressed relative to those of either of the optically pure components. A further marked reduction in growth rates is recorded for the stereoblock polymer. An analysis of the linear spherulite radial growth rates in terms of the Hoffman-Lauritzen treatment gave evidence of the development of larger folds, hence a rougher lamellar surface in the stereoblock poisoner than in the polyenantiomers.

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Section: Introductionsupporting

confidence: 87%

Section: Tc(adfmentioning

confidence: 99%

Optically Active Polyethers. 1. Studies of the Crystallization in Blends of the Enantiomers and the Stereoblock Form of Poly(epichlorohydrin)

Singfield¹,

Brown²

1995

Macromolecules

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“…This discrepancy can be attributed to the difference between the hydrodynamic volumes of the polymers and the polystyrene standards. However, the M n values determined by NMR spectroscopy and by Maldi‐TOF spectrometry are in very good agreement with the corresponding theoretical values, confirming the “living” character of these polymerizations 19…”

Section: Resultssupporting

confidence: 79%

Stereocomplex formation between enantiomeric poly(α‐methyl‐α‐ethyl‐β‐propiolactones): Effect of molecular weight

Fraschini

Pennors

Prud’homme

2007

J Polym Sci B Polym Phys

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“…Figure 4 shows the X-ray patterns of the atactic (#R1, left picture) and optically active (#05, right picture) poly (PhPL) samples. The same crystalline peaks (or rings) are seen in both cases at 2 8 = 8.6 (vs), 16.9 (vs), 20.7 ( m ) , 22.9 (m), and 26.8 (w) [vs = very strong, m = medium, and w = weak intensity] although the intensity is clearly larger (for a similar irradiated volume) for the optically active sample, in agreement with the DSC results. piolactone) 2,5,10, [14][15][16][17]28…”

Section: Physical Propertiessupporting

confidence: 58%

Synthesis and polymerization of racemic and optically active substituted β‐propiolactones. VI. α‐Phenyl β‐propiolactone

Hmamouchi

Prud’homme

1991

J. Polym. Sci. A Polym. Chem.

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The synthesis and optical resolution of α‐phenyl β‐amino‐ethylpropionate led to the preparation of optically active α‐phenyl β‐propiolactones (PhPL) of different optical purities. The enantiomeric excess of PhPL was determined using 200 MHz 1H‐NMR spectroscopy, after complexation with tris[3‐(trifluoromethyl hydroxymethylene)‐d‐camphorato]europium III. It was then polymerized, in bulk and in solution, using a potassium acetate/crown ether complex as initiator. The optically active poly(PhPL)s thus obtained are insoluble in most organic solvents, whereas atactic poly(PhPL)s are soluble in CCl4, CHCl3, and dichloroethane. Several differences are observed between the physical properties of optically active and atactic poly(PhPL)s. However, atactic poly(PhPL)s are semi‐crystalline polymers, similar to poly(α‐disubstituted β‐propiolactone)s, but in contrast with poly(α‐methyl β‐propiolactone). Melting (Tf) and glass transition temperatures, as well as enthalpy of fusion (ΔH), vary with the optical purity of the polymers. For example, atactic poly(PhPL) exhibits a Tf = 94°C and ΔH = 9 J/g as compared to Tf = 119°C and ΔH = 37 J/g for a poly(PhPL) having an enatiomeric excess of 50%.

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Preparation, characterization, and porperties of optically active poly(α‐methyl‐α‐ethyl‐β‐propiolactones)

Cited by 29 publications

References 40 publications

Optically Active Polyethers. 1. Studies of the Crystallization in Blends of the Enantiomers and the Stereoblock Form of Poly(epichlorohydrin)

Optically Active Polyethers. 1. Studies of the Crystallization in Blends of the Enantiomers and the Stereoblock Form of Poly(epichlorohydrin)

Stereocomplex formation between enantiomeric poly(α‐methyl‐α‐ethyl‐β‐propiolactones): Effect of molecular weight

Synthesis and polymerization of racemic and optically active substituted β‐propiolactones. VI. α‐Phenyl β‐propiolactone

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