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Journal of Polymer Research

Erschienen in:

01.03.2015 | Original Paper

Effect of matrix morphology on mechanical and barrier properties of polypropylene nanocomposite films containing preferentially aligned organoclay platelets

verfasst von: Patrapon Sanguansat, Taweechai Amornsakchai

Erschienen in: Journal of Polymer Research | Ausgabe 3/2015

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Abstract

The objective of this research was to study and optimize the effect of matrix morphology on the desirable mechanical and barrier properties of polypropylene/organoclay (PP/clay) nanocomposite films. Nanocomposites with different organoclay contents and three different matrix morphologies were compared with neat PP under identical conditions. The degree of organoclay dispersion was controlled through the use of a compatibilizer, maleic anhydride grafted polypropylene (PP-g-MA). The nanocomposite films were first prepared by melt casting and then subjected to annealing and re-crystallization. Organoclay platelets in all films were found to align parallel to the film plane. Crystalline PP in as-prepared films was found to have a preferred orientation with the lamellae normally lying perpendicular to the machine direction. Upon annealing, the stacks of parallel lamellae, aligned perpendicular to the machine direction and the film surface, tend to be more orderly than in as-prepared films (see models). No crystal orientation was found in re-crystallized films. A clear increase in elastic modulus and tensile strength with increasing organoclay content was observed. Relative oxygen permeability (ROP) of nanocomposite films decreased with increasing amount of organoclay. The effect of matrix morphology is as follows: annealed films display the highest elastic modulus, tensile strength and ROP, followed by as-prepared and re-crystallized films.

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Nielsen LE (1967) Models for the permeability of filled polymer systems. J Macromol Sci A 1(5):929–942CrossRef

Cussler EL, Hughes SE, Ward WJ, Aris R (1988) Barrier membranes. J Membr Sci 38:161–174CrossRef

Bharadwaj RK (2001) Modeling the barrier properties of polymer-layer silicate nanocomposites. Macromolecules 34:9189–9192CrossRef

Galgali G, Agarwal S, Lele A (2004) Effect of clay orientation on the tensile modulus of polypropylene-nanoclay composites. Polymer 45(17):6059–6069CrossRef

Choudalakis G, Gotsis AD (2009) Permeability of polymer/clay nanocomposites: a review. Eur Polym J 45(4):967–984CrossRef

Xu B, Zheng Q, Song Y, Shangguan Y (2006) Calculating barrier properties of polymer/clay nanocomposites: effects of clay layers. Polymer 47(8):2904–2910CrossRef

Dong W, Liu Y, Zhang X, Gao J, Huang F, Song Z, Tan B, Qiao J (2005) Preparation of high barrier and exfoliated-type nylon-6/ultrafine full-vulcanized powdered rubber/clay nanocomposites. Macromolecules 38:4551–4553CrossRef

Fereydoon M, Tabatabaei SH, Ajji A (2014) Properties of co-extruded nanoclay-filled aliphatic nylon (PA6)/linear low-density polyethylene and aromatic nylon (MXD6)/linear low-density polyethylene multilayer films. J Plast Film Sheet. doi:10.1177/8756087914528348

Choi WJ, Kim HJ, Yoon KH, Kwon OH, Hwang CI (2006) Preparation and barrier property of poly(ethylene terephthalate)/clay nanocomposite using clay-supported catalyst. J Appl Polym Sci 100(6):4875–4879CrossRef

10.

Tsai TY, Li CH, Chang CH, Cheng WH, Hwang CL, Wu RJ (2005) Preparation of exfoliated polyester/clay nanocomposites. Adv Mater 17(14):1769–1773CrossRef

11.

Villaluenga JPG, Khayet M, Lopez-Manchado MA, Valentin JL, Seoane B, Mengual JI (2007) Gas transport properties of polypropylene/clay composite membrances. Eur Polym J 43(4):1132–1143CrossRef

12.

Mirzadeh A, Kokabi M (2007) The effect of composition and draw-down ratio on morphology and oxygen permeability of polypropylene nanocomposite blow films. Eur Polym J 43(9):3757–3765CrossRef

13.

Miltner HE, Assche GV, Pozsgay A, Pukansky B, Mele BV (2006) Restricted chain segment mobility in poly(amide) 6/clay nanocomposites evidenced by quasi-isothermal crystallization. Polymer 47(3):826–835CrossRef

14.

Langhe D, Hiltner A, Baer E (2011) Melt crystallization of syndiotactic polypropylene in nanolayer confinement impacting structure. Polymer 52(25):5879–5889CrossRef

15.

Lu C, Mai YW (2007) Permeability modeling of polymer-layered silicate nanocomposites. Compos Sci Technol 67(14):2895–2902CrossRef

16.

BL1.3W:SAXS (2014) Synchrotron Light Research Institute, Nakhon Ratchasima. http://www.slri.or.th/en/index.php?option=com_content&view=article&id=3&Itemid=85,%20accessed%2015/12/2013. Accessed 27 Aug 2014

17.

Zhu PW, Edward G (2008) Orientation distribution of parent-daughter structure of isotactic polypropylene: a study using simultaneous synchrotron WAXS and SAXS. J Mater Sci 43:6459–6467CrossRef

18.

Dean DM, Rebenfeld L, Register RA (1998) Matrix molecular orientation in fiber-reinforced polypropylene composites. J Mater Sci 33:4797–4812CrossRef

19.

Sadeghi F, Ajji A, Carreau PJ (2007) Analysis of row nucleated lamellar morphology of polypropylene obtained from the cast film process: effect of melt rheology and process conditions. Polym Eng Sci 47(7):1170–1178CrossRef

20.

Tabatabaei SH, Carreau PJ, Ajji A (2009) Structure and properties of MDO stretched polypropylene. Polymer 50(16):3981–3989CrossRef

21.

Cole KC, Ajji A (1999) Orientation characterization in polypropylene. Kluwer Publishers, Dordrecht

22.

Solarski S, Ferreira M, Devaux E (2005) Characterization of the thermal properties of PLA fibers by modulated differential scanning calorimetry. Polymer 46(25):11187–11192CrossRef

23.

Moore JR, Edward P (1996) Polypropylene handbook. Hanser-Gardner Publication, Inc., Cincinnati

24.

Kim DH, Fasulo PD, Rodgers WR, Paul DR (2007) Structure and properties of polypropylene-based nanocomposites: effect of PP-g-MA to organoclay ratio. Polymer 48(18):5308–5323CrossRef

25.

Dong Y, Bhattacharyya D (2008) Effects of clay type, clay/compatibilizer content and matrix viscosity on the mechanical properties of polypropylene/organoclay nanocomposites. Compos A-Appl S 39:1177–1191CrossRef

26.

Hegde RR, Bhat GS, Spruiell JE, Benson R (2013) Structure and properties of polypropylene-nanoclay composites. J Polym Res 20:323–335CrossRef

27.

Lei SG, Hoa SV, Ton-that MT (2006) Effect of clay types on the processing and properties of polypropylene nanocomposites. Compos Sci Technol 66(10):1274–1279CrossRef

28.

Nozue Y, Shinohara Y, Ogawa Y, Sakurai T, Hori H, Kasahara T, Yamaguchi N, Yagi N, Amemiya Y (2007) Deformation behavior of isotactic polypropylene spherulite during hot drawing investigated by simultaneous microbeam SAXS-WAXS and POM measurement. Macromolecules 40(6):2036–2045CrossRef

29.

Stribeck N, Nochel U, Camarillo AA, Roth SV, Dommach M, Bosecke P (2007) SAXS study of oriented crystallization of polypropylene from a quiescent melt. Macromolecules 40(13):4535–4545CrossRef

30.

Kalapakdee A, Amornsakchai T (2014) Mechanical properties of preferentially aligned short pineapple leaf fiber reinforced thermoplastic elastomer: Effects of fiber content and matrix orientation. Polym Test 37:36–44CrossRef

31.

Maiti P, Hikosaka M, Yamada K, Toda A, Gu F (2000) Lamellae thickening in isotactic polypropylene with high tacticity crystallized at high temperature. Macromolecules 33(24):9069–9075CrossRef

32.

Lai SM, Chen WC, Zhu XS (2009) Melt mixed compatibilized polypropylene/clay nanocomposites: part 1- the effect of compatibilizers on optical transmittance and mechanical properties. Compos A-Appl S 40(6–7):754–765CrossRef

33.

Somwangthanaroj A, Lee EC, Solomon MJ (2003) Early stage quiescent and flow-induced crystallization of intercalated polypropylene nanocomposites by time-resolved light scattering. Macromolecules 36:2333–2342CrossRef

34.

Liang Y, Cao W, Li Z, Wang Y, Wu Y, Zhang L (2008) A new strategy to improve the gas property of isobutylene-isoprene rubber/clay nanocomposites. Polym Test 27(3):270–276CrossRef

35.

Tarapow JA, Bernal CR, Alvaraz VA (2008) Mechanical properties of polypropylene/clay nanocomposites: effect of clay content, polymer/clay compatibility, and processing conditions. J Appl Polym Sci 111(2):768–778

36.

Yuan W, Guo M, Miao Z, Liu Y (2010) Influence of maleic anhydride grafted polypropylene on the dispersion of clay in polypropylene/clay nanocomposites. Polym J 42:745–751CrossRef

37.

Ghelichi M, Qazvini NT, Jafari SH, Khonakdar HA, Reuter U (2012) Nanoclay dispersion in a miscible blend: an assessment through rheological analysis. J Polym Res 19:9830–9838CrossRef

38.

Chiu FC, Chu PH (2006) Characterization of solution-mixed polypropylene/clay nanocomposites without compatibilizers. J Polym Res 13:73–78CrossRef

39.

Dumont MJ, Reyna-Valencia A, Emond JP, Bousmina M (2006) Barrier properties of polypropylene/organoclay nanocomposites. J Appl Polym Sci 103(1):618–625CrossRef

40.

Roozemond PC, Ma Z, Cui K, Li L, Peters GWM (2014) Multimorphological crystallization of Shish-Kebab structures in isotactic polypropylene: quantitative modeling of parent–daughter crystallization kinetics. Macromolecules 47(25):5152–5162CrossRef

41.

Kang J, Xiong B, Liu D, Cao Y, Chen J, Yang F, Xiang M (2014) Understanding in the morphology and tensile behavior of isotactic polypropylene cast films with different stereo-defect distribution. J Polym Res 21:485–494CrossRef

Titel: Effect of matrix morphology on mechanical and barrier properties of polypropylene nanocomposite films containing preferentially aligned organoclay platelets
verfasst von: Patrapon Sanguansat
Taweechai Amornsakchai
Publikationsdatum: 01.03.2015
Verlag: Springer Netherlands
Erschienen in: Journal of Polymer Research / Ausgabe 3/2015
Print ISSN: 1022-9760
Elektronische ISSN: 1572-8935
DOI: https://doi.org/10.1007/s10965-015-0676-8

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