High refractive index organic–inorganic nanocomposites: design, synthesis and application

Lü, Changli; Yang, Bai

doi:10.1039/b816254a

Cited by 352 publications

(159 citation statements)

References 171 publications

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“…Lack of optical transmission in AAO membrane is due to surface light scattering and limitations for light diffusion through the thickness (60 &m) of membrane. In transparent organic-inorganic composites, filler size, composite surface roughness and refractive index (RI) difference [18] between inorganic phase and matrix might be responsible for their transparency. The light transmission percentages of annealed and unannealed composites are demonstrated in Figure 5a.…”

Section: Light Transmittance Of Nanocompositesmentioning

confidence: 99%

Superior thermal conductivity of transparent polymer nanocomposites with a crystallized alumina membrane

Poostforush¹,

Azizi²

2014

Express Polym. Lett.

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Abstract. The properties of novel thermoconductive and optically transparent nanocomposites have been reported. The composites were prepared by the impregnation of thermoset resin into crystallized anodic aluminum oxide (AAO). Crystallized AAO synthesized by annealing amorphous AAO membrane at 1200°C. Although through-plane thermal conductivity of nanocomposites improved up to 1.13 W·m -1 ·K -1 (39 vol% alumina) but their transparency was preserved (T !550 nm~ 72%). Integrated annealed alumina phase, low refractive index mismatch between resin and alumina and formation of nano-optical fibers through the membrane resulted in such marvel combination. This report shows a great potential of these types of nanocomposites in 'heat management' of lightening devices.

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Section: Light Transmittance Of Nanocompositesmentioning

confidence: 99%

Superior thermal conductivity of transparent polymer nanocomposites with a crystallized alumina membrane

Poostforush¹,

Azizi²

2014

Express Polym. Lett.

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“…Some high refractive index polymer nanocomposites reported in literature were prepared with ZrO 2 (n=2.16 at 589 nm) 24 and ZnO (n=2.00 at 589 nm) 25 that, like TiO 2 , show also photocatalytic properties 26 . Moreover, TiO 2 is most often used as inorganic phase due to the higher refractive index and its easier preparation in both laboratory and industry 27 .…”

Section: Introductionmentioning

confidence: 99%

Highly transparent poly(2-ethyl-2-oxazoline)-TiO₂nanocomposite coatings for the conservation of matte painted artworks

et al. 2015

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“…With the argon plasma treatment discussed above an approximately 1 µm thick polyimide film could also be spin-coated on top of Cytop. To increase the refractive index one can incorporate high refractive index nanoparticles, such as metal oxides, into the core layer [16], [17], [18], [19] . Since the thickness of the core layer has to be on a scale of hundreds of nanometres, the nanoparticles must be much smaller than these characteristic dimensions to obtain a uniform material with acceptable low scattering for the optical application.…”

Section: Construction Of the Optical Layer Stackmentioning

confidence: 99%

Design and process development of a photonic crystal polymer biosensor for point-of-care diagnostics

et al. 2011

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In this work, we report advances in the fabrication and anticipated performance of a polymer biosensor photonic chip developed in the European Union project P3SENS (FP7-ICT4-248304). Due to the low cost requirements of point-ofcare applications, the photonic chip is fabricated from nanocomposite polymeric materials, using highly scalable nanoimprint-lithography (NIL). A suitable microfluidic structure transporting the analyte solutions to the sensor area is also fabricated in polymer and adequately bonded to the photonic chip.We first discuss the design and the simulated performance of a high-Q resonant cavity photonic crystal sensor made of a high refractive index polyimide core waveguide on a low index polymer cladding. We then report the advances in doped and undoped polymer thin film processing and characterization for fabricating the photonic sensor chip. Finally the development of the microfluidic chip is presented in details, including the characterisation of the fluidic behaviour, the technological and material aspects of the 3D polymer structuring and the stable adhesion strategies for bonding the fluidic and the photonic chips, with regards to the constraints imposed by the bioreceptors supposedly already present on the sensors.

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High refractive index organic–inorganic nanocomposites: design, synthesis and application

Cited by 352 publications

References 171 publications

Superior thermal conductivity of transparent polymer nanocomposites with a crystallized alumina membrane

Superior thermal conductivity of transparent polymer nanocomposites with a crystallized alumina membrane

Highly transparent poly(2-ethyl-2-oxazoline)-TiO₂nanocomposite coatings for the conservation of matte painted artworks

Design and process development of a photonic crystal polymer biosensor for point-of-care diagnostics

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High refractive index organic–inorganic nanocomposites: design, synthesis and application

Cited by 352 publications

References 171 publications

Superior thermal conductivity of transparent polymer nanocomposites with a crystallized alumina membrane

Superior thermal conductivity of transparent polymer nanocomposites with a crystallized alumina membrane

Highly transparent poly(2-ethyl-2-oxazoline)-TiO2nanocomposite coatings for the conservation of matte painted artworks

Design and process development of a photonic crystal polymer biosensor for point-of-care diagnostics

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Highly transparent poly(2-ethyl-2-oxazoline)-TiO₂nanocomposite coatings for the conservation of matte painted artworks