Products - Anatase Nanowires B1       
Research Grade
Industry Grade
Cat. No.
Production Description
Anatase nanowires B1,
Industry grade
SEM image of NovaWire-ATiO-B1-RD
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XRD of NovaWire-ATiO-B1-RD
Cat. No.
Production Description
Anatase nanowires B1,
Research grade
Ceramic Nanowires
Semiconductive Nanowires
Metallic Nanowires
Compound Nanowires
Coating and Membrane
Grade Nanowires
Ceramic Nanotubes
Other Nanostructures
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The product has unique physicochemical properties, such as non-toxicity, insolubility, high thermal
stability and chemical inertness, which ensure its great performance in high temperatures and other
harsh environments. And also it is a good semiconductor with high photoactivity. Moreover, it has
high refractive index and unique ability to reflect light, which allow it to be used in many optical
applications, e.g., imparting whiteness, brightness, and opacity to various end-use products.

Average diameter: 10nm
Appearance: dry white powder
Crystalline phase: pure anatase
Copyright © 2014 Novarials Corporation All rights reserved.

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dioxide nanowires, titanium dioxide, titanium(IV) oxide nanowires, titanium(IV) oxide nanofibers,
titanium(IV) oxide, TiO
2 nanowires, TiO2 nanofibers, TiO2,  anatase nanowire, anatase nanofiber,
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dioxide nanofiber, titanium dioxide nanowire, titanium(IV) oxide nanowire, titanium(IV) oxide
nanofiber, TiO
2 nanowire, TiO2 nanofiber

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  4. M. Wagemaker, A. P.M. Kentjens, and F. M. Mulder, “Equilibrium lithium transport between
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  5. Armstrong, G.; Armstrong, A. R.; Bruce, P. G.; Reale, P.; Scrosati, B., “ TiO2(B) Nanowires
    as an Improved Anode Material for Lithium-Ion Batteries Containing LiFePO4 or LiNi0.5Mn1.
    5O4 Cathodes and a Polymer Electrolyte”, Adv. Mater., 2006, 18, 2597.
  6. D. Wang, A. Chen,   S. H. Jang, H. L. Yip and   A. K.-Y. Jen, “Sensitivity of titania(B)
    nanowires to nitroaromatic and nitroamino explosives at room temperature via surface
    hydroxyl groups”, J. Mater. Chem., 2011, 21, 7269.
  7. J.H. Park, S. Kim, and A.J. Bard, “Novel carbon-doped TiO2 nanotube arrays with high
    aspect ratios for efficient solar water splitting”, Nano Letters, 2006, 6, 24.
  8. Zeng, T.-W.; Lin, Y.-Y.; Lo, H.-H.; Chen, C.-W.; Chen, C.-H.; Liou, S.-C.; Huang, H.-Y.;
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  9. Lin, Y. Y.; Chu, T. H.; Li, S. S.; Chuang, C. H.; Chang, C. H.; Su, W. F.; Chang, C. P.; Chu,
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    3, 343.
  14. Ru-Hua Tao, Jin-Ming Wu, Hong-Xing Xue, Xiao-Mei Song, Xu Pan, Xia-Qin Fang, X. D.
    Fang, and S. Y. Dai, “A novel approach to titania nanowire arrays as photoanodes of back-
    illuminated dye-sensitized solar cells”, Journal of Power Sources, 2010, 195, 2989.
  15. J. X. Liu, D. Z. Yang, F. Shi, and Y. J. Cai, “Sol-gel deposited TiO2 film on NiTi surgical alloy
    for biocompatibility improvement,” Thin Solid Films, 2003, 429, 225.
  16. G. Giavaresi, L. Ambrosio, and L. Ambrosio, “Histomorphometric, ultrastructural and
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    Gratzel, M., “Sequential deposition as a route to high-performance perovskite-sensitized
    solar cells”, Nature, 2013, 499, 316.

  • Fillers for various nanocomposites including nanowire polymer composites, nanowire metal
    composite, and nanowire ceramic composites
  • Fillers for various adhesives and paints
  • Fillers for various high performance films
  • Nanowire porous ceramic membranes for chemical and water filtration, which can used in
    strong acids and bases
  • High temperature non-woven textiles
  • White pigments for plastics, paints, rubbers, cosmetics, man-made fibers, papers, and
  • Surface coatings
  • Catalyst supports
  • Photocatalysts
  • Dye-sensitized, polymer-based, and quantum dot (QD) solar cells (photovoltaic and
    photocatalytic cells)
  • Water splitting for hydrogen production
  • Chemical sensors, especially high temperature gas sensors
  • Anodes of lithium ion batteries
  • Fuel cells
  • Supercapacitors
  • Detoxification
  • Drug delivery
  • Biosensors
  • Biocompatible materials for bone implants
  • Electrochromic devices