Chemistry of inorganic compounds – Oxygen or compound thereof – Metal containing
Reexamination Certificate
2001-06-18
2004-12-28
Silverman, Stanley (Department: 1754)
Chemistry of inorganic compounds
Oxygen or compound thereof
Metal containing
C252S584000
Reexamination Certificate
active
06835368
ABSTRACT:
TECHNICAL FIELD
The invention relates to the field of photorefractive crystal material.
BACKGROUND ART
Three-dimensional optical storage will enter the market, but it does not mean that the product has been done very well. The main problem is no excellent three-dimensional optical storage material found. In fact, scientists in the world have been looking for satisfied three-dimensional optical storage material for a long time. Up to now, the iron doped lithium niobate is still considered as the first candidate. But there are big shortcomings for LiNbO
3
:Fe, such as a too long response time and a low ability to resist optic scattering (A. Hellemans, Holograms can storage terabytes, but where? Science 286 (1999) 1502). Now, improving and optimizing the properties of LiNbO
3
:Fe crystal (restrain the laser induced voltage effect and maintain its good photorefraction properties in the mean time) is still the most important task at present.
DISCLOSURE OF THE INVENTION
The objection of this invention is to supply a doubly doped lithium niobate crystal, which is an improvement and optimization of LiNbO
3
:Fe, and has an excellent photorefractive properties, and can be used as the three-dimensional holographic optical storage material.
The doubly doped lithium niobate crystal of the invention is doped with iron and a second radius-matched metal ion in the meantime. Its composition can be denoted as Li
1−x
Nb
1+y
O
3
:Fe
m
,M
n
, where M is magnesium, indium, or zinc; when using q to denote the ion valence of M (q=2 when M is Mg or Zn, and q=3 when M is In), the values of x, y, m, and n are in the range of 0.05≦x≦0.13, 0.00≦y≦0.01, 5.0×10
−5
≦m≦7.5×10
−4
, and 0.02≦qn≦0.13, respectively.
The composition of doubly doped lithium niobate crystals can:
doped with 0.007~0.03 wt. % Fe and 1.0~5.0 mol. % Mg,
doped with 0.01~0.05 wt. % Fe and 0.75~3.0 mol. % In, or
doped with 0.02~0.06 wt. % Fe and 1.5~6.5 mol. % Zn,
While the congruent composition is [Li]/[Nb]=0.87~0.95.
The implement steps of the invention are:
(1) Weigh up Li
2
CO
3
, Nb
2
O
3
, Fe
2
O
3
, and MgO, In
2
O
3
or ZnO powders according to the crystal composition, and dry them at 120~150° C. for 25 hours, then thoroughly mix them at a mixer lasting for 24 hours, and keep them at 800~850° C. for 2~5 hours to make Li
2
CO
3
decompose sufficiently, and then sinter at 1050~1150° C. for 2~8 hours to obtain doubly doped lithium niobate powder. (2) Put the above doped lithium niobate powder into a Pt crucible after impacted then heat the powder by a middle frequency stove. Grow the doubly doped lithium niobate crystals using the Czochralski pulling method along c or a axis via the procedures of necking, shouldering, uniform-diametering, and tailing, with the pulling rate being 1~3 mm/h, the rotation rate being 15~30 rpm, the temperature difference of the melt-crystal interface being 20° C., the temperature gradient in the melt volume near the surface being 1.5° C./mm, and the temperature gradient above the melt surface being 1.0° C./mm, respectively. (3) Pole and anneal the grown doped lithium niobate crystals at 1200° C. to obtain a single-domain structure.
REFERENCES:
Alexander Hellemans, Frontier In Optics, Science,Holograms Can Store Terabytes, But Where?, vol. 286, pp. 1502-1504, Nov. 19, 1999.
Guangyin Zhang et al., Department of Physics, Nankai University, Tianji, China,Study of Resistance Against Photorefractive Light-Induced Scattering, SPIE vol. 2529, pp. 14-17. 1995.
Amnon Yariv et al., T.J. Watson Laboratory, California Institute of Technology, Pasadena, California,Holographic Storage Dynamics in Lithium Niobate: Theory and Experiment, vol. 13, No. 11, pp. 2513-2523, Nov. 1996.
IBM Holographic Optical Storage Team, Laser Focus World,Holographic Storage Delivers High Data Density, pp. 123-127, Dec. 2000.
Chen Shaolin
Chen Xiaojun
Huang Hui
Huang Ziheng
Kong Yongfa
Armstrong Kratz Quintos Hanson & Brooks, LLP
Nankai University
Silverman Stanley
Strickland Jonas N.
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