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Journal of Polymer Research

Erschienen in:

01.06.2013 | Original Paper

Effect of surface interactions on the glass transition temperature behavior of amorphous polystyrene

verfasst von: Wei Ding, Rachel F. Sanchez, Meghan R. Ruggles, Paul Bernazzani

Erschienen in: Journal of Polymer Research | Ausgabe 6/2013

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Abstract

The glass transition temperatures (T _g) of nanosized thin polystyrene (PS) films were determined using FTIR (or, more specifically, the absorbance peak at 797 cm⁻¹). This novel method was used to verify the presence of surface interactions between polymer and substrate. As surface interactions may lead to changes in T _g, various amounts of nanoparticles of TiO₂ and of ZnSe were uniformly deposited on the surface of free-standing PS film to simulate increases in surface interactions. FTIR spectra of thin PS films coated with various amounts of these nanoparticles were recorded as a function of temperature, and the T _g values obtained using this method were compared to results obtained using conventional differential scanning calorimetry (DSC). The addition of TiO₂ nanoparticles leads to an increase in T _g, while the addition of ZnSe depresses the glass transition temperature. Both effects are linear with respect to the amount of nanoparticles. These results support the argument that increasing surface interactions leads to changes in chain mobility, as determined from variations in T _g.

Vorheriger Artikel Synthesis, characterization and morphology of polyanthranilic acid micro- and nanostructures

Nächster Artikel Molecularly imprinted electrospun nanofibers for adsorption of nickel-5,10,15,20-tetraphenylporphine (NTPP) in organic media

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Fryer DS, Nealey PF, de Pablo JJ (2000) Thermal probe measurements of the glass transition temperature for ultrathin polymer films as a function of thickness. Macromolecules 33(17):6439–6447CrossRef

Cheng W et al (2007) Elastic properties and glass transition of supported polymer thin films. Macromolecules 40(20):7283–7290CrossRef

Cho S-J, Boo J-H (2012) Characteristics of multilayered plasma-polymer thin films using toluene and TEOS by PECVD. Microelectron Eng 89:19–22CrossRef

Jenekhe SA (1987) Polymer processing to thin films for microelectronic applications. In: Bowden MJ, Turner SR (eds) Polymers for high technology. American Chemical Society, Washington, DC, pp 261–269

Meredith JC et al (2000) Combinatorial materials science for polymer thin-film dewetting. Macromolecules 33(26):9747–9756CrossRef

Andrew JG (1998) Lubricants and overcoats for magnetic storage media. Curr Opin Colloid Interface Sci 3(4):368–372CrossRef

Fryer DS et al (2001) Dependence of the glass transition temperature of polymer films on interfacial energy and thickness. Macromolecules 34(16):5627–5634CrossRef

Kerle T et al (2001) Mobility of polymers at the air/polymer interface. Macromolecules 34(10):3484–3492CrossRef

Roth CB, Dutcher JR (2005) Glass transition and chain mobility in thin polymer films. J Electroanal Chem 584(1):13–22CrossRef

10.

Tseng KC, Turro NJ, Durning CJ (2000) Tracer diffusion in thin polystyrene films. Polymer 41(12):4751–4755CrossRef

11.

Dinelli F et al (2011) Nanoscale viscoelastic behavior of the surface of thick polystyrene films as a function of temperature. Macromolecules 44(4):987–992CrossRef

12.

Vignaud G et al (2005) Multiple glass-transition temperatures in thin supported films of isotactic PMMA as revealed by enhanced Raman scattering. Langmuir 21(19):8601–8604CrossRef

13.

Hudzinskyy D et al (2011) Effects of strong confinement on the glass-transition temperature in simulated atactic polystyrene films. Macromolecules 44(7):2299–2310CrossRef

14.

Svanberg C (2006) Glass transition relaxations in thin suspended polymer films. Macromolecules 40(2):312–315CrossRef

15.

Kim JH, Jang J, Zin W-C (2000) Estimation of the thickness dependence of the glass transition temperature in various thin polymer films. Langmuir 16(9):4064–4067CrossRef

16.

Keddie JL, Jones RAL, Cory RA (1994) Size-dependent depression of the glass transition temperature in polymer films. Europhys Lett 27(1):59CrossRef

17.

Forrest JA et al (1996) Effect of free surfaces on the glass transition temperature of thin polymer films. Phys Rev Lett 77(19):4108CrossRef

18.

Sharp JS, Forrest JA (2003) Free surfaces cause reductions in the glass transition temperature of thin polystyrene films. Phys Rev Lett 91(23):235701CrossRef

19.

Jain TS, de Pablo JJ (2002) Monte Carlo simulation of free-standing polymer films near the glass transition temperature. Macromolecules 35(6):2167–2176CrossRef

20.

Yousfi M et al (2009) A novel method for studying the dynamics of polymers confined in spherical nanoparticles in nanoblends. Macromolecules 42(6):2190–2197CrossRef

21.

Dalnoki-Veress K et al (2000) Glass transition reductions in thin freely-standing polymer films: a scaling analysis of chain confinement effects. J Phys IV France 10(PR7):Pr7-221–Pr7-226CrossRef

22.

Roth CB et al (2007) Eliminating the enhanced mobility at the free surface of polystyrene: fluorescence studies of the glass transition temperature in thin bilayer films of immiscible polymers. Macromolecules 40(7):2568–2574CrossRef

23.

Kim JH, Jang J, Zin W-C (2001) Thickness dependence of the glass transition temperature in thin polymer films. Langmuir 17(9):2703–2710CrossRef

24.

Keddie JL, Jones RAL, Cory RA (1994) Interface and surface effects on the glass-transition temperature in thin polymer films. Faraday Discuss 98:219–230CrossRef

25.

Torres JA, Nealey PF, de Pablo JJ (2000) Molecular simulation of ultrathin polymeric films near the glass transition. Phys Rev Lett 85(15):3221CrossRef

26.

Bernazzani P et al (2008) Determination of the glass transition temperature of thin unsupported polystyrene films using interference fringes. Thin Solid Films 516(21):7947–7951CrossRef

27.

Bernazzani P, Sanchez R (2008) Effect of substrate interactions on the melting behavior of thin polyethylene films. Eur Phys J E 26(4):427–434CrossRef

28.

Tretinnikow ON, Zbankow RG (2004) FTIR spectroscopic evidence of lowered chain interpenetration in thin polymer films. Macromolecules 37:3543–3545CrossRef

29.

Xu S, O’Connell PA, McKenna GB (2010) Unusual elastic behavior of ultrathin polymer films: confinement-induced/molecular stiffening and surface tension effects. J Chem Phys 132:184902CrossRef

30.

Wu Y, Song L, Hu Y (2012) Thermal properties and combustion behaviors of polystyrene/surface-modified TiO₂ nanotubes nanocomposites. Polymer-Plast Tech Eng 51(6):647–653CrossRef

31.

Zou JP, Zhao Y, Yang MJ, Dan Y (2008) UV-resistant performance of polystyrene/TiO₂ composite particles containing organic UV-stabilizer groups. Polym Polym Compos 16(3):209–216

32.

Wang ZB, Pang HT, Li GC, Zhang ZK (2006) Glass transition and free volume of high impact polystyrene/TiO₂ nanocomposites determined by dilatometry. J Macromol Sci Part Phys 45(5):689–697CrossRef

Titel: Effect of surface interactions on the glass transition temperature behavior of amorphous polystyrene
verfasst von: Wei Ding
Rachel F. Sanchez
Meghan R. Ruggles
Paul Bernazzani
Publikationsdatum: 01.06.2013
Verlag: Springer Netherlands
Erschienen in: Journal of Polymer Research / Ausgabe 6/2013
Print ISSN: 1022-9760
Elektronische ISSN: 1572-8935
DOI: https://doi.org/10.1007/s10965-013-0146-0

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