Preparation and Optical Storage Properties of λ­Ti3O5 Powder

doi:10.3724/SP.J.1077.2013.12309

Abstract

Abstract:

The Ti₃O₅ powder was prepared by reducing TiO₂ nanopartical in H₂ atmosphere. The samples were investigated by powder X-ray diffraction (XRD), Fourier transform infrared spectroscope (FTIR), scanning electron microscope (SEM) and UV-Vis diffusion reflectance spectra (UV-Vis). The results show that, single phase Ti₃O₅ can be obtained by increasing the H₂ flow. When H₂ flow increases from 0.3 mL/min to 0.8 mL/min, the single phase λ-Ti₃O₅ can be synthesized using SiO₂-coated TiO₂ (rutile, nanoparticle) as raw material at 1150℃ for 1 h. While using nano-TiO₂ powders without SiO₂-coated as raw material, the reduction product is multiphases composed of λ-Ti₃O₅ and β-Ti₃O₅. There is a high reflectivity contrast between λ-Ti₃O₅ and β-Ti₃O₅. When the multiphases sample is irradiated with 532 nm 20 ns-pulsed laser light at room temperature, Ti₃O₅ will transit from α phase to β phase, which shows a good optical storage performance.

Key words: &#x003bb, -Ti₃O₅, powder, reduction, nano-TiO₂, optical storage

CLC Number:

TB383

LIU Gang, HUANG Wan-Xia, YI Yong. Preparation and Optical Storage Properties of λTi₃O₅ Powder[J]. Journal of Inorganic Materials, 2013, 28(4): 425-430.

Figures/Tables 11

Fig. 1 Relationship of Gibbs free energy and pressure quotient at different temperature

Fig. 2 XRD patterns of the SiO2-coated TiO2 powder (rutile) after reduction in H2 atmosphere at different temperatures for 1 h

Fig. 3 XRD patterns of the SiO2-coated TiO2 powder(rutile) after reduction in H2 atmosphere at 1150℃ for different time

Table 1 Effect of raw material and H2 flow on the composition of reduction product

Number	TiO₂	T/℃ t/h	H₂/(L·min^-1)	Composition
1	A	1150 1	0.3	Ti₄O₇,Ti₃O₅
2	R	1150 1	0.3	Ti₄O₇,Ti₃O₅
3	A	1150 1	0.8	Ti₃O₅
4	R	1150 1	0.8	Ti₃O₅

Fig. 4 IR spectra of different nano-TiO2

Fig. 5 SEM images of different nano-TiO2

Fig. 6 XRD patterns of the different nano-TiO2 after reduction in H2 atmosphere at 1150℃ for 1 h

Fig. 7 SEM images of different TiO2 powder after reduction in H2 atmosphere at 1150℃ for 1 h

Fig. 8 Wavelength dependence of reflection difference between the β-Ti3O5 and λ-Ti3O5

Table 2 Reflectivity contrast between β-Ti3O5(R1) and λ-Ti3O5(R2)

Wavelength/nm	R₁/%	R₂/%	C/%
310	27.8	11.9	79.9
350	12.7	6.0	71.1
480	9.0	4.7	62.1
750	6.6	2.8	82.1

Fig. 9 XRD patterns of the Ti3O5 powder before and after 532 nm laser light irradiation at room temperature

References 13

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Preparation and Optical Storage Properties of λTi₃O₅ Powder

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