Controlled Nano-Oxide Layer Coating on Fine Particles with Multiple Optical-Electrical Functions

Wen Cheng J. Wei; B.Y. Yu; J.F. Li; C.S. Chen

doi:10.4028/www.scientific.net/KEM.313.37

Paper Titles

Microstructure and Dielectric Properties of Heat-Treated SiC-AlN Multiphase Ceramics
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Model Prediction of Thermodynamics Activity in Multicomponent Liquid Alloy
p.19

Mg-Y-Cu Bulk Nanocrystalline Matrix Composites Containing WC Particles
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Discontinuously Reinforced Aluminum Composite and Its Application in Brake Discs
p.31

Controlled Nano-Oxide Layer Coating on Fine Particles with Multiple Optical-Electrical Functions
p.37

Influence of Stackers of Particles on Piezoelectricity of 0-3 Type Piezo-Composite
p.43

Strengthening Zirconia by Adding Both Nickel and Alumina Particles
p.47

Evaluating Mechanical Properties of Hard Coatings by Using Relativity Method
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On the High Pure Alumina Composite Powder for Sintering at 1400°C, A Preliminary Investigation
p.59

HomeKey Engineering MaterialsKey Engineering Materials Vol. 313Controlled Nano-Oxide Layer Coating on Fine...

Controlled Nano-Oxide Layer Coating on Fine Particles with Multiple Optical-Electrical Functions

Abstract:

SiO2 core/TiO2 shell composite particles were synthesized by four different heterogeneous coagulation techniques. The configurations of the composite particles and the microstructure of assembly were characterized by SEM and TEM. The colloidal stability of nano-particles was also computer-simulated by a discrete element method (DEM) in consideration of Brownian motion occurring on the nano-particles. The results indicated that uniform adsorption of the fine particle absolutely needed fine tuning of surface charging conditions and processing steps.

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Periodical:

Key Engineering Materials (Volume 313)

Pages:

37-42

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.313.37

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Online since:

July 2006

Authors:

Wen Cheng J. Wei, B.Y. Yu, J.F. Li, C.S. Chen

Keywords:

Coating, Mono-Size, PBG Crystal, SiO₂, Titania (TiO₂)

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