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Journal of Materials Science

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01-03-2014

Colloidal particles with various glass transition temperatures: preparation, assembly, and the properties of stop bands under heat treatment

Authors: Chunmei Li, Baoliang Zhang, Jiaojun Tan, Xinlong Fan, Yali Liu, Hepeng Zhang, Qiuyu Zhang

Published in: Journal of Materials Science | Issue 6/2014

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Abstract

Monodisperse P(St-co-nBA-co-AA) colloidal microspheres with various glass transition temperatures (T _gs), whose average particle sizes were about 300 nm, were prepared using soap-free emulsion polymerization by adjusting the ratio of styrene and n-butyl acrylate. Colloidal photonic crystals were assembled with these microspheres by vertical deposition method. Stop bands of colloidal crystals under different temperatures have been characterized. The relationship between the stop band and temperature was indicated. The microstructure and reflectance spectra of photonic crystals were characterized by SEM and fiber spectrometer, respectively. Results showed that as the temperature increased, only a little red shift of stop band appeared in the vicinity of T _g and the intensity of the maximum reflection peak decreased until the stop bands disappeared. Furthermore, enough heating time at the T _g ±2 °C could also lead to the disappearance of stop bands. What’s more, colloidal crystal films with certain connection strength were obtained by simple heating.

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Yablonovitch E (1987) Inhibited spontaneous emission in solid-state physics and electronics. Phys Rev Lett 58:2059–2062CrossRef

John S (1987) Strong localization of photons in certain disordered dielectric superlattices. Phys Rev Lett 58:2486–2489CrossRef

Xia Y, Gates B, Yin Y, Lu Y (2000) Monodispersed colloidal spheres: old materials with new applications. Adv Mater 12:693–713CrossRef

Moon JH, Yang S (2010) Chemical aspects of three-dimensional photonic crystals. Chem Rev 110:547CrossRef

Ge J, Hu Y, Zhang T, Huynh T, Yin Y (2008) Self-assembly and field-responsive optical diffractions of superparamagnetic colloids. Langmuir 24:3671–3680CrossRef

Zhao Y, Zhao X, Sun C, Li J, Zhu R, Gu Z (2008) Encoded silica colloidal crystal beads as supports for potential multiplex immunoassay. Anal Chem 80:1598–1605CrossRef

Tang B, Zhao X, Zhao Y, Zhang W, Wang Q, Kong L, Gu Z (2011) Binary optical encoding strategy for multiplex assay. Langmuir 27:11722–11728CrossRef

Tsuji S, Kawaguchi H (2005) Colored thin films prepared from hydrogel microspheres. Langmuir 21:8439–8442CrossRef

Kang P, Ogunbo SO, Erickson D (2011) High resolution reversible color images on photonic crystal substrates. Langmuir 27:9676–9680CrossRef

10.

Ge J, Yin Y (2008) Magnetically tunable colloidal photonic structures in alkanol solutions. Adv Mater 20:3485–3491CrossRef

11.

Bonifacio LD, Lotsch BV, Puzzo DP, Scotognella F, Ozin GA (2009) Stacking the nanochemistry deck: structural and compositional diversity in one-dimensional photonic crystals. Adv Mater 21:1641–1646CrossRef

12.

Lotsch BV, Scotognella F, Moeller K, Bein T and Ozin GA (2010) Stimuli-responsive Bragg stacks for chemo-optical sensing applications. In: Proceedings of SPIE, Photonics, Brussels. doi:10.111712.854703

13.

Lotsch BV, Knobbe CB, Ozin GA (2009) A step towards optically encoded silver release in 1D photonic crystals. Small 5:1498–1503CrossRef

14.

Von Freymann G, Kitaev V, Lotsch BV, Ozin GA (2013) Bottom-up assembly of photonic crystals. Chem Soc Rev 42:2528–2554CrossRef

15.

Colodrero S, Forneli A, López-López C, Pellejà L, Míguez H, Palomares E (2012) Efficient transparent thin dye solar cells based on highly porous 1D photonic crystals. Adv Funct Mater 22:1303–1310CrossRef

16.

Scotognella F, Puzzo DP, Monguzzi A, Wiersma DS, Maschke D, Tubino R, Ozin GA (2009) Nanoparticle one-dimensional photonic-crystal dye laser. Small 5:2048–2052CrossRef

17.

Zhang JT, Wang L, Lamont DN, Velankar SS, Asher SA (2012) Fabrication of large-area two-dimensional colloidal crystals. Angew Chem Int Ed 51:6117–6120CrossRef

18.

Nelson EC, Dias NL, Bassett KP, Dunham SN, Verma V, Miyake M, Wiltzius P, Rogers JA, Coleman JJ, Li X (2011) Epitaxial growth of three-dimensionally architectured optoelectronic devices. Nat Mater 10:676–681CrossRef

19.

Vlasov YA, Bo X-Z, Sturm JC, Norris DJ (2001) On-chip natural assembly of silicon photonic bandgap crystals. Nature 414:289–293CrossRef

20.

Zakhidov AA, Baughman RH, Iqbal Z, Cui C, Khayrullin I, Dantas SO, Marti J, Ralchenko VG (1998) Carbon structures with three-dimensional periodicity at optical wavelengths. Science 282:897–901CrossRef

21.

Norris DJ, Vlasov YA (2001) Chemical approaches to three-dimensional semiconductor photonic crystals. Adv Mater 13:371–376CrossRef

22.

Stöber W, Fink A, Bohn E (1968) Controlled growth of monodisperse silica spheres in the micron size range. J Colloid Interface Sci 26:62–69CrossRef

23.

Agrawal M, Fischer D, Gupta S, Zafeiropoulos NE, Pich A, Lidorikis E, Stamm M (2010) Three-dimensional colloidal crystal arrays exhibiting stop band in near-infrared region. J Phys Chem C 114:16389–16394CrossRef

24.

Bailey J, Sharp JS (2010) Thin film polymer photonics: spin cast distributed Bragg reflectors and chirped polymer structures. Eur Phys J E 33:41–49CrossRef

25.

Zhang X, Zhang J, Zhu D, Li X, Zhang X, Wang T, Yang B (2010) A universal approach to fabricate ordered colloidal crystals arrays based on electrostatic self-assembly. Langmuir 26:17936–17942CrossRef

26.

Li C, Fan X, Zhou L, Zhang B, Yin D, Zhang Q (2013) Preparation and assembly performance of colloidal particles of photonic crystals with controlled photonic band gaps. J Polym Res 20:1–7

27.

Ko YG, Shin DH (2007) Effects of liquid bridge between colloidal spheres and evaporation temperature on fabrication of colloidal multilayers. J Phys Chem B 111:1545–1551CrossRef

28.

Mcmullan JM, Wagner NJ (2012) Directed self-assembly of colloidal crystals by dielectrophoretic ordering. Langmuir 28:4123–4130CrossRef

29.

Vermolen E, Kuijk A, Filion L, Hermes M, Thijssen J, Dijkstra M, Van Blaaderen A (2009) Fabrication of large binary colloidal crystals with a NaCl structure. Proc Natl Acad Sci 106:16063–16067CrossRef

30.

Hynninen A-P, Thijssen JH, Vermolen EC, Dijkstra M, Van Blaaderen A (2007) Self-assembly route for photonic crystals with a bandgap in the visible region. Nat Mater 6:202–205CrossRef

31.

Ngo T, Liddell C, Ghebrebrhan M, Joannopoulos J (2006) Tetrastack: colloidal diamond-inspired structure with omnidirectional photonic band gap for low refractive index contrast. Appl Phys Lett 88:241920–241923CrossRef

32.

Leunissen ME, Christova CG, Hynninen AP, Royall CP, Campbell AI, Imhof A, Dijkstra M, Van Roij R, Van Blaaderen A (2005) Ionic colloidal crystals of oppositely charged particles. Nature 437:235–240CrossRef

33.

Mayoral R, Requena J, Moya JS, López C, Cintas A, Miguez H, Meseguer F, Vázquez L, Holgado M, Blanco (1997) 3D Long-range ordering in ein SiO2 submicrometer-sphere sintered superstructure. Adv Mater 9:257–260CrossRef

34.

Xu X, Goponenko AV, Asher SA (2008) Polymerized polyHEMA photonic crystals: pH and ethanol sensor materials. J Am Chem Soc 130:3113–3119CrossRef

35.

Zhang JT, Wang L, Luo J, Tikhonov A, Kornienko N, Asher SA (2011) 2-D array photonic crystal sensing motif. J Am Chem Soc 133:9152–9155CrossRef

36.

Xuan R, Wu Q, Yin Y, Ge J (2011) Magnetically assembled photonic crystal film for humidity sensing. J Mater Chem 21:3672–3676CrossRef

37.

Griffete N, Dybkowska M, Glebocki B, Basinska T, Connan C, MaîTre AS, Chehimi MM, Slomkowski S, Mangeney C (2010) Thermoresponsive colloidal crystals built from core-shell poly (styrene/α-tert-butoxy-ω-vinylbenzylpolyglycidol) microspheres. Langmuir 26:11550–11557CrossRef

38.

Hu Z, Lu X, Gao J (2001) Hydrogel opals. Adv Mater 13:1708–1712CrossRef

39.

Takeoka Y, Seki T (2006) Visualizing conformations of subchains by creating optical wavelength-sized periodically ordered structure in hydrogel. Langmuir 22:10223–10232CrossRef

40.

Zhou M, Xing F, Ren M, Feng Y, Zhao Y, Qiu H, Wang X, Gao C, Sun F, He Y (2009) A facile method to assemble PNIPAM-containing microgel photonic crystals. Chem Phys Chem 10:523–526CrossRef

41.

Hu S, Rieger J, Roth SV, Gehrke R, Leyrer RJ, Men Y (2008) GIUSAXS and AFM studies on surface reconstruction of latex thin films during thermal treatment. Langmuir 25:4230–4234CrossRef

42.

Wohlleben W, Bartels FW, Boyle M, Leyrer RJ (2008) Covalent and physical cross-linking of photonic crystals with 10-fold-enhanced chemomechanical stability. Langmuir 24:5627–5635CrossRef

43.

Wohlleben W, Bartels FW, Altmann S, Leyrer RJ (2007) Mechano-optical octave-tunable elastic colloidal crystals made from core-shell polymer beads with self-assembly techniques. Langmuir 23:2961–2969CrossRef

44.

Schäfer CG, Gallei M, Zahn J, Engelhardt J, Hellmann GP, Rehahn M (2013) Thermo-and mechano-responsive elastomeric polymer opal films, reversible light. Chem Mater 25:2309–2318CrossRef

45.

Sadakane M, Sasaki K, Nakamura H, Yamamoto T, Ninomiya W, Ueda W (2012) Important property of polymer spheres for the preparation of three-dimensionally ordered macroporous (3DOM) metal oxides by the ethylene glycol method: the glass-transition temperature. Langmuir 28:17766–17770CrossRef

46.

Gaillard N, Guyot A, Claverie J (2003) Block copolymers of acrylic acid and butyl acrylate prepared by reversible addition–fragmentation chain transfer polymerization: synthesis, characterization, and use in emulsion polymerization. J Polym Sci Part A 41:684–698CrossRef

47.

Ji J, Yan L, Xie D (2008) Surfactant-free synthesis of amphiphilic diblock copolymer in aqueous phase by a self-stability process. J Polym Sci Part A 46:3098–3107CrossRef

48.

Luo Y, Wang X, Zhu Y, Li B-G, Zhu S (2010) Polystyrene-block-poly (n-butyl acrylate)-block-polystyrene triblock copolymer thermoplastic elastomer synthesized via RAFT emulsion polymerization. Macromolecules 43:7472–7481CrossRef

49.

Kim BJ, Kang KS (2012) Fabrication of a crack-free large area photonic crystal with colloidal silica spheres modified with vinyltriethoxysilane. Cryst Growth Des 12:4039–4042CrossRef

50.

Puzzo DP, Arsenault AC, Manners I, Ozin GA (2009) Electroactive inverse opal: a single material for all colors. Angew Chem 121:961–965CrossRef

51.

Lin Y, Hui C, Jagota A (2001) The role of viscoelastic adhesive contact in the sintering of polymeric particles. J Colloid Interface Sci 237:267–282CrossRef

52.

Haiat G, Huy P, Barthel E (2003) The adhesive contact of viscoelastic spheres. J Mech Phys Solids 51:69–99CrossRef

53.

Pursiainen OL, Baumberg JJ, Ryan K, Bauer J, Winkler H, Viel B, Ruhl T (2005) Compact strain-sensitive flexible photonic crystals for sensors. Appl Phys Lett 87:101902–101903CrossRef

54.

Viel B, Ruhl T, Hellmann GP (2007) Reversible deformation of opal elastomers. Chem Mater 19:5673–5679CrossRef

55.

Pursiainen OL, Baumberg JJ, Winkler H, Viel B, Spahn P, Ruhl T (2008) Shear-induced organization in flexible polymer opals. Adv Mater 20:1484–1487CrossRef

Title: Colloidal particles with various glass transition temperatures: preparation, assembly, and the properties of stop bands under heat treatment
Authors: Chunmei Li
Baoliang Zhang
Jiaojun Tan
Xinlong Fan
Yali Liu
Hepeng Zhang
Qiuyu Zhang
Publication date: 01-03-2014
Publisher: Springer US
Published in: Journal of Materials Science / Issue 6/2014
Print ISSN: 0022-2461
Electronic ISSN: 1573-4803
DOI: https://doi.org/10.1007/s10853-013-7970-9

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