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Colloid and Polymer Science
Erschienen in: Colloid and Polymer Science 6/2014

01.06.2014 | Original Contribution

Rigid amorphous fraction and melting behavior of poly(ethylene terephthalate)

verfasst von: Maria Cristina Righetti, Michele Laus, Maria Laura Di Lorenzo

Erschienen in: Colloid and Polymer Science | Ausgabe 6/2014

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Abstract

The multiple melting behavior of poly(ethylene terephthalate) (PET) is generally attributed to the fusion of original crystals recrystallized during the heating at conventional scanning rate. In the present study, the triple and double melting behavior that is observed after isothermal crystallization at T c lower and higher than 215 °C, respectively, is put in relation with the presence and absence of rigid amorphous fraction around the original primary crystal lamellae. The complex melting behavior is explained by assuming that two different morphologies of primary crystals develop during crystallization at temperatures lower than 215 °C, in a proportion that is a function of the crystallization temperature: chain cluster aggregations with a high percentage of rigid amorphous fraction on the boundaries and small crystals with a high percentage of adjacent reentry folding and reduced constraints at the amorphous/crystal interphase. These distinct morphologies differently transform upon heating at low scanning rate, originating two endotherms. On the contrary, after crystallization at T c  > 215 °C, all the primary crystalline structure, which probably are characterized by the same morphology made of tightly chain folded lamellae and absence of rigid amorphous fraction, undergo the same reorganization route, originating a single endotherm.
Vorheriger Artikel Metal-enhanced fluorescence using silver nanoparticles-embedded polyelectrolyte multilayer films for microarray-based immunoassays
Nächster Artikel Epitaxial single crystal surface patterning and study of physical and chemical environmental effects on crystal growth

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Literatur
1.
Wunderlich B (2005) Thermal analysis of polymeric materials. Springer, New York
2.
Wunderlich B (2003) Reversible crystallization and the rigid amorphous phase in semicrystalline macromolecules. Prog Polym Sci 28:383–450CrossRef
3.
Di Lorenzo ML, Righetti MC (2008) The three-phase structure of isotactic poly(1-butene). Polymer 49:1323–1331CrossRef
4.
Martin S, Exposito MT, Vega JF, Martinez-Salazar J (2013) Microstructure and properties of branched polyethylene: application of a three-phase structural model. J Appl Polym Sci 128:1871–1878
5.
Lin J, Shenogin S, Nazarenko S (2002) Oxygen solubility and specific volume of rigid amorphous fraction in semicrystalline poly(ethylene terephthalate). Polymer 43:4733–4743CrossRef
6.
Guinault A, Sollogoub C, Ducruet V, Domenek S (2012) Impact of crystallinity of poly(lactide) on helium and oxygen barrier properties. Eur Polym J 48:779–788CrossRef
7.
Kolesov I, Androsch R (2012) The rigid amorphous fraction of cold-crystallized polyamide 6. Polymer 53:4770–4777CrossRef
8.
Delpouve N, Stoclet G, Saiter A, Dargent E, Marais S (2012) Water barrier properties in biaxially drawn poly(lactic acid) films. J Phys Chem B 16:4615–4625CrossRef
9.
Schick C, Wurm A, Mohamed A (2001) Vitrification and devitrification of the rigid amorphous fraction of semicrystalline polymers revealed from frequency-dependent heat capacity. Colloid Polym Sci 279:800–806CrossRef
10.
Schick C, Wurm A, Mohammed A (2003) Formation and disappearance of the rigid amorphous fraction in semicrystalline polymers revealed from frequency dependent heat capacity. Thermochim Acta 396:119–132CrossRef
11.
Xu X, Ince S, Cebe P (2003) Development of the crystallinity and rigid amorphous fraction in cold-crystallized isotactic polystyrene. J Polym Sci Polym Phys 41:3026–3036CrossRef
12.
Xu H, Cebe P (2004) Heat capacity study of isotactic polystyrene: dual reversing crystal melting and relaxation of rigid amorphous fraction. Macromolecules 37:2797–2806CrossRef
13.
Righetti MC, Tombari E, Di Lorenzo ML (2008) Crystalline, mobile amorphous and rigid amorphous fractions in isotactic polystyrene. Eur Polym J 44:2659–26676CrossRef
14.
Androsch R, Wunderlich B (2005) The link between rigid amorphous fraction and crystal perfection in cold-crystallized poly(ethylene terephthalate). Polymer 46:12556–12566CrossRef
15.
Righetti MC, Tombari E, Angiuli M, Di Lorenzo ML (2007) Enthalpy-based determination of crystalline, mobile amorphous and rigid amorphous fractions in semicrystalline polymers: poly(ethylene terephthalate). Thermochim Acta 462:15–24CrossRef
16.
Chen H, Cebe P (2009) Vitrification and devitrification of rigid amorphous fraction of PET during quasi-isothermal cooling and heating. Macromolecules 42:288–292CrossRef
17.
Ma Q, Georgiev G, Cebe P (2011) Constraints in semicrystalline polymers: using quasi-isothermal analysis to investigate the mechanisms of formation and loss of the rigid amorphous fraction. Polymer 52:4562–4570CrossRef
18.
Righetti MC, Di Lorenzo ML, Tombari E, Angiuli M (2008) The low-temperature endotherm in poly(ethylene terephthalate): partial melting and rigid amorphous fraction mobilization. J Phys Chem B 112:4233–4241CrossRef
19.
Righetti MC, Tombari E (2011) Crystalline, mobile amorphous and rigid amorphous fractions in poly(L-lactic acid) by TMDSC. Thermochim Acta 522:118–127CrossRef
20.
Di Lorenzo ML, Gazzano M, Righetti MC (2012) The role of the rigid amorphous fraction on cold crystallization of poly(3-hydroxybutyrate). Macromolecules 45:5684–5691CrossRef
21.
Righetti MC, Tombari E, Di Lorenzo ML (2013) The role of the crystallization temperature on the nanophase structure evolution of poly[(R)-3-hydroxybutyrate]. J Phys Chem B 117:12303–12311CrossRef
22.
Di Lorenzo ML, Righetti MC, Cocca M, Wunderlich B (2010) Coupling between crystal melting and rigid amorphous fraction mobilization in poly(ethylene terephthalate). Macromolecules 43:7689–7694CrossRef
23.
Bicerano J (1998) Crystallization of polypropylene and poly(ethylene terephthalate). J Macromol Sci C Polym Rev J 38:391–479CrossRef
24.
Groeninckx G, Reynaers H, Berghmans H, Smets G (1980) Morphological and melting behaviour of semicrystalline poly(ethylene terephthalate) I isothermally crystallized PET. J Polym Sci Polym Phys Ed 18:1311–1324CrossRef
25.
Groeninckx G, Reynaers H (1980) Morphological and melting behaviour of semicrystalline poly(ethylene terephthalate) II annealed PET. J Polym Sci Polym Phys Ed 18:1325–1341CrossRef
26.
Fontaine F, Ledent J, Groeninckx G, Reynaers H (1982) Morphological and melting behaviour of semicrystalline poly(ethylene terephthalate):3. Quantification of crystal perfection and crystallinity. Polymer 23:185–191CrossRef
27.
Alfonso GC, Pedemonte E, Ponzetti L (1979) Mechanism of densification and crystal perfection of poly(ethylene terephthalate). Polymer 20:104–112CrossRef
28.
Jonas AM, Russell TP, Yoon DY (1994) Time resolved SAXS studies of morphological changes in cold crystallized poly(ethylene terephthalate) during annealing and heating. Colloid Polym Sci 272:1344–1351CrossRef
29.
Ivanov DA, Pop T, Yoon DY, Jonas AM (2002) Direct observation of crystal-amorphous interphase in lamellar semicrystalline poly(ethylene terephthalate). Macromolecules 35:9813–9818CrossRef
30.
Wang Z-G, Hsiao BS, Sauer BB, Kampert WG (1999) The nature of secondary crystallization in poly(ethylene terephthalate). Polymer 40:4615–4627CrossRef
31.
Alvarez C, Šics I, Nogales A, Denchev Z, Funari SS, Ezquerra TA (2004) Structure-dynamics relationship in crystallizing poly(ethylene terephthalate) as revealed by time-resolved X-ray and dielectric methods. Polymer 45:3953–3959CrossRef
32.
Flores A, Pieruccini M, Nöchel U, Stribeck N, Baltá Calleja FJ (2008) Recrystallization studies on isotropic cold-crystallized PET: influence of heating rate. Polymer 49:965–973CrossRef
33.
Zhou C, Clough SB (1988) Multiple melting endotherms of poly(ethylene terephthalate). Polym Eng Sci 28:65–68CrossRef
34.
Lu XF, Hay JN (2001) Isothermal crystallization and melting behaviour of poly(ethylene terephthalate). Polymer 42:9323–9431
35.
Medellin-Rodriguez FJ, Phillips PJ, Lin JS, Campos R (1997) The triple melting behaviour of poly(ethylene terephthalate): molecular weight effects. J Polym Sci B Polym Phys 35:1757–1774CrossRef
36.
Kong Y, Hay JN (2003) Multiple melting behaviour of poly(ethylene terephthalate). Polymer 44:623–633CrossRef
37.
Minakov AA, Mordvintsev DA, Tol R, Schick C (2006) Melting and reorganization of the crystalline fraction and relaxation of the rigid amorphous fraction of isotactic polystyrene on fast heating (30,000 K/min). Thermochim Acta 442:25–30CrossRef
38.
Pan P, Inoue Y (2009) Polymorphism and isomorphism in biodegradable polyesters. Prog Polym Sci 34:605–640CrossRef
39.
Müller AJ, Arnal ML (2005) Thermal fractionation of polymers. Prog Polym Sci 30:559–603CrossRef
40.
Righetti MC, Laus M (2000) The biphasic behaviour of a thermotropic polymesomorphic polyester I. Time evolution of phase separation. Polymer 41:8355–8362CrossRef
41.
Righetti MC, Laus M (2001) Biphasic behaviour of a thermotropic polymesomorphic polyester II. Temperature evolution of phase separation. Macromolecules 34:7190–7196CrossRef
42.
Giani E, Sparnacci K, Laus M, Palamone G, Kapeliouchko V, Arcella V (2003) PTFE-polystyrene core-shell nanospheres and nanocomposites. Macromoelcules 36:4360–4367CrossRef
43.
Righetti MC, Boggioni A, Laus M, Antonioli D, Sparnacci K, Boarino L (2013) Thermal and mechanical properties of PES/PTFE composites and nanocomposites. J Appl Polym Sci 130:3624–3633CrossRef
44.
Capaccio G, Ward IM (1974) Preparation of ultra-high modulus linear polyethylenes; effect of molecular weight and molecular weight distribution on drawing behaviour and mechanical properties. Polymer 15:233–238CrossRef
45.
Sarge SM, Hemminger W, Gmelin E, Höhne GWH, Cammenga HK, Eysel W (1997) Metrologically bases procedures for the temperature, heat and heat flow rate calibration of DSC. J Therm Anal 49:1125–1134CrossRef
46.
Wunderlich B (1997) Modeling the heat flow and heat capacity of modulated differential scanning calorimetry. J Therm Anal 48:207–224CrossRef
47.
Wurm A, Merzlyakov M, Schick C (1998) Reversible melting probed by temperature modulated dynamic mechanical and calorimetric measurements. Colloid Polym Sci 276:289–296CrossRef
48.
Androsch R, Moon I, Kreitmeier S, Wunderlich B (2000) Determination of heat capacity with a sawtooth–type, power compensated temperature modulated DSC. Thermochim Acta 357–358:267–278CrossRef
49.
Di Lorenzo ML, Wunderlich B (2003) Melting of polymers by non-isothermal, temperature-modulated calorimetry: analysis of various irreversible latent heat contributions to the reversing heat capacity. Thermochim Acta 405:255–268CrossRef
50.
51.
Righetti MC, Di Lorenzo ML (2011) Melting temperature evolution of non-reorganized crystals. Poly(3-hydroxybutyrate). Thermochim Acta 512:59–66CrossRef
52.
Schick C, Merzlyakov M, Wunderlich B (1998) Analysis of the reorganization of poly(ethylene terephthalate) in the melting range by temperature-modulated calorimetry. Polym Bull 40:297–303CrossRef
53.
Ishikiriyama K, Wunderlich B (1997) Melting of poly(oxyethylene) analyzed by tempertaure-modulated calorimetry. Macromolecules 30:4126–4131CrossRef
54.
Righetti MC (1999) Reversible melting in poly(butylene terephthalate). Thermochim Acta 330:131–135CrossRef
55.
Al-Hussein M, Strobl G (2002) The melting line, the crystallization line, and the equilibrium melting temperature of isotactic polystyrene. Macromolecules 35:1672–1676CrossRef
56.
Denchev Z, Nagales A, Ezquerra TA, Fernandes-Nascimento J, Baltà-Calleja FJ (2000) On the origin of the multiple melting behaviour in poly(ethylene naphthalate-2,6-dicarboxylate): microstructural study as revealed by differential scanning calorimetry and x-ray scattering. J Polym Sci B Polym Phys 38:1167–1182CrossRef
Metadaten
Titel
Rigid amorphous fraction and melting behavior of poly(ethylene terephthalate)
verfasst von
Maria Cristina Righetti
Michele Laus
Maria Laura Di Lorenzo
Publikationsdatum
01.06.2014
Verlag
Springer Berlin Heidelberg
Erschienen in
Colloid and Polymer Science / Ausgabe 6/2014
Print ISSN: 0303-402X
Elektronische ISSN: 1435-1536
DOI
https://doi.org/10.1007/s00396-014-3198-8

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