Growth and Optical Spectra of Zn∶Er∶LiNbO_3 Crystals Using Bridgman Method

The growth of LiNbO3 single crystal with Er^3＋ and Zn^2＋ co-doped using Bridgman method and its characteristic absorption spectra and fluorescence spectra were reported. Large-size crystals initially containing Zn^2＋ （3%） and Er^3＋ （0.6%） with good optical quality were obtained using optimized conditions such as a growth rate of 0.8- 1.5 mm·h^-1 and a temperature gradient of about 30 - 35℃·cm^-1 across the solid-liquid interface and the sealed platinum crucible. X-ray diffraction and differential thermal analysis （DTA） were used to characterize the crystals. The results indicate that the concentration of Er^3＋ ions in crystals, their absorption intensity, and their fluorescence intensity decrease from the bottom to the top in the crystals. However, for the upper part of the crystal, the up-conversion fluorescence intensity is higher than that of the lower part excited by an 800 or 970 nm pump. The effects of the crystal lattice, their structural defect and their effective segregation of Er^3＋ ions were discussed with respect to the variations of the up-conversion fluorescence intensity.

Growth and Optical Spectra of Zn∶Er∶LiNbO_3 Crystals by Bridgman Method

The growth of LiNbO3 single crystal with Er^3＋/Zn^2＋ co-doped by the bridgman method and the characteristics of absorption spectra and fluorescence spectra were reported. By means of the optimized con- ditions such as growth rate of 0.8 - 1.5 mm · h^- 1, temperature gradient about 30 - 35℃ ·cm^-1 across the solid-liquid interface and sealed platinum, large size crystals containing Zn^2＋ （3%） and Er^3＋ （0.6%） with good optical quality were obtained. X-ray diffraction and DTA were used to characterize the crystals. The results indicate that the concentration of Er^3＋ ions in crystals decrease along the growth direction, the absorption intensity and the fluorescence intensity ions also decrease along the growth direction. of Er^3＋ However, for the upper part crystal, the upconversion fluorescence intensity is higher than that of the lower part crystal excited with 800 or 970 nm pump. The effects of crystal lattice, structure defect and effective segregation of Er^3＋ ions were discussed in respect to the variations were discussed of upconversion fluorescence intensity.

Domain Reversal Characteristics of Near-Stoichiometric LiNbO3 Crystals

The domain reversal characteristics of near-stoichiometric LiNbO3 ([Li]/[Li+Nb]=0.496) single crystals, which are grown by the Czochralski method with K2O tlux, are investigated. The switch tield for 180° ferroelectric domain reversal in the near-stoichiometric LiNbO3 crystal is 8.0±0.5kV/mm, which is only one third of the switching field required for the congruent LiNbO3 crystals. We have successfully achieved 180° domain reversal in near-stoichiometric LiNbO3 samples of 1.0mm thickness.

Transmission Spectral Characteristics of Photonic Crystals Milled in Annealed Proton-Exchange LiNbO_3 Waveguide

Transmission spectra of triangular lattice photonic crystals milled in the top surface of an annealed proton- exchange waveguide are numerically simulated. The effects of the finite depth, conical shape, trapezoidal shape and hybrid shape of holes are theoretically analyzed. Due to the difficulty of milling high aspect-ratio cylindrical holes in lithium niobate （LiNbO3 ）, a compromised solution is proposed to improve the overlap between shallow holes and the waveguide mode, and useful transmission spectra with strong contrast and sharp band edges are achieved.

Effect of Zn^(2+) Ions on Upconversion Emission of Er^(3+) in Zn/Er:LiNbO_3 Crystal

The effect of Zn 2＋ ions codoped on the upconversion emission of Er 3＋ ions in Er：LiNbO 3 crystal under different excitation wavelength was reported.The upconversion emission spectra of Zn/Er：LiNbO 3 following 800 nm excitation reveal an enhanced green emission and a suppressed red emission simultaneously.The cross relaxation processes（2 H11/2 ＋ 4 I13/2 → 4 I11/2 ＋ 4 F9/2 and 4 F7/2 ＋ 4 I11/2 → 4 F9/2 ＋ 4 F9/2） are responsible for populating the red 4 F 9/2 emitting state.The dissociation effect of Zn2＋ ions on the Er 3＋ cluster sites makes these cross relaxation processes inefficient.Under 980 nm excitation,the Zn 2＋ codoped leads to the decreased intensities of green and red upconversion emissions.These reductions are attributed to the inefficient cross relaxation processes（4 I11/2 ＋ 4 I11/2 → 4 F7/2 ＋ 4 I15/2 and 4 F7/2 ＋ 4 I11/2 → 4 F9/2 ＋ 4 F9/2） caused by the same dissociation effect of Zn 2＋ ions.

Improvement of photorefractive properties in Hf:Fe:LiNbO_3 crystals with various [Li]/[Nb] ratios

Photorefractive properties of Hf：Fe：LiNbO3 crystals with various [Li]/[Nb] ratios have been investigated at 488 nm wavelength based on the two-wave coupling experiment. High diffraction efficiency and large recording sensitivity are observed and explained. The decrease in Li vacancies is suggested to be the main contributor to the increase in the photoconductivity and subsequently to the induction of the improvement of recording sensitivity. The saturation diffraction efficiency is measured up to 80.2%, and simultaneously the recording sensitivity of 0.91 cm/J is achieved to in the Hf：Fe：LiNbO3 crystal grown from the melt with the [Li]/[Nb] ratio of 1.20, which is significantly enhanced as compared with those of the Hf：Fe：LiNbO3 crystal with the [Li]/[Nb] ratio of 0.94 in melt under the same experimental conditions. Experimental results definitely show that increasing the [Li]/[Nb] ratio in crystal is an effective method＇for Hf：Fe：LiNbO3 crystal to improve its photorefractive properties.

Studies of Photorefractive Crystals of Double-Doped Ce,Fe:LiNbO_3

In this paper, photorefractive crystals of Ce, Fe:LiNbO 3 are systematically studied. The crystals have been grown by Czochralski method. The samples with different doping concentrations and oxidation/reduction treatments have been fabricated. Their photorefractive properties were experimentally investigated by using two beam coupling. The results show that the photorefractive efficiency depends on the dopant concentration, oxidation/reduction treatment, and light wavelength. The doping mechanism is also discussed here.

Ultraviolet laser-induced photovoltaic effects in miscut ferroelectric LiNbO_3 single crystals

This paper investigates the photovoltaic properties of miscut LiNbO3 single crystal with different thicknesses under irradiation of a 248 nm ultraviolet laser pulse with 20 ns duration without an applied bias. Nanosecond photovoltaic response is observed and faster rise time is obtained in thinner samples. In accord with the 248 nm laser duration, the full width at half maximum of the photovoltaic signals keeps a constant of ~ 20 ns. With decrease of the crystal thickness, the photovoltaic sensitivity was improved rapidly at first and then decreased, and the maximum photovoltage occurred at 0.38 mm-thick single crystal. The present results demonstrate that decreasing the LiNbO3 single crystal thickness can obtain faster response time and improve the photovoltaic sensitivity.

Effect of Hf^(4+) doping on structure and enhancement of upconversion luminescence in Yb:Tm:LiNbO_3 crystals

A series of Yb：Tm：LiNbO_3 crystals doped with x mol% Hf^（4＋）ions（x = 2, 4, and 6） were grown by the Czochralski method. The dopant occupancy and defect structure of Hf：Yb：Tm：LiNbO_3 crystals were investigated by x-ray diffraction and infrared transmission spectra. The influence of Hf^（4＋）ions concentration on UV–VIS–NIR absorption spectra of Hf：Yb：Tm：LiNbO_3 crystals was discussed. The upconversion luminescence of Hf：Yb：Tm：LiNbO_3 crystals was obtained under 980 nm excitation. Strong emissions were observed at 475 nm in the blue wavelength range and 651 nm in the red wavelength range. Remarkably, enhancement of the red and blue upconversion luminescence was achieved by tridoping Hf^（4＋）ions.

Influence of Oxidation and Reduction Treatments on the Photorefractive Properties of Mg:In:Fe:LiNbO_3 Crystals

A series of Mg：In：Fe：LiNbO3 crystals were grown by Czochralski technique; their absorption spectra and photo scattering resistance ability after oxidation or reduction treatment were measured by light spot distortion method, and their response time and exponential gain coefficient were tested by two-beam coupling experiment. Besides, the effective carrier concentration has been calculated. The results showed that the absorption edges of reduced and oxidized crystals are respectively shifted to violet and Einstein compared with those of the growth state crystal. From oxidation state to growth state to reduction state of the samples, the photo scattering resistance ability and response time decrease while the exponential gain coefficient and concentration of effective carriers increase. The reduction treatment was necessary for the Mg：In：Fe：LiNbO3 crystals to enhance their photorefractive properties.

Study on the Growth and Photorefractive Properties of In:Fe:Cu:LiNbO_3 Crystals

Fe（0.2 mol%）：Cu（0.04 mol%）：LiNbO3 crystals with different doping concentration of In^3＋ （0, 1.0, 2.0, 3.0mol%） were grown by Czochralski method, and then oxidized and reduced. The infrared transmittance spectra of crystals were measured to investigate the location of doping ion and its threshold concentration. The photorefractive properties of the crystals were tested by two beam coupling experiment. The results showed that the threshold concentration of In ions is 2.0～ 3.0 mol% and In ions take the place of NbLi^4＋ to form （ InLi^2＋） before reaching its threshold concentration, and then the location of normal Nb ions. In the （2.0 mol%）：Fe：Cu：LiNbO3 crystal with the oxidation treatment having the highest diffraction efficiency （η = 45.8%）, the photo-damage resistance threshold value R of In（3.0 mol%）：Fe：Cu：LiNbO3 was 3.67×10^4 W/cm^2 which was two orders of magnitude higher than that of Fe：Cu：LiNbO3 crystal （4.30×10^2 W/cm^2）. And the photo-damage resistance ability was enhanced by oxidized treatment. The In（2.0～3.0 mol%）：Fe：Cu：LiNbO3 crystals with oxidized treatment have the best photorefractive properties.

Holographic Storage Properties of In:Fe:Mn:LiNbO_3 Crystals

In：Fe：Mn：LiNbO3（LN） crystals were grown in air atmosphere by Czochralski method with different concentration of In （0, 1, 2, 3 mol%） in the melts, while the contents of Fe2O3 and MnO were 0.1 and 0.5 mol%, respectively. The location of doping ions was analyzed by Ultravioletvisible absorption spectra and differential thermal analysis. The diffraction efficiency （η）, writing time （τw） and erasure time （τe） of the crystals were measured by two-beam coupling experiment. The dynamic range and photorefractive sensitivity have also been calculated. The results showed that with the increase of In ions in the melt, the absorption edge of In：Fe：Mn：LN crystal shifts to the violet firstly and then makes the Einstein shift, the Curie temperature of crystal increases firstly and then decreases, the storage ratio speeds up, diffraction efficiency decreases, and dynamic range and photorefractive sensitivity increase. The mechanism of holographic storage properties of In：Fe： Mn：LN crystal with different doping concentration of In^3＋ was investigated, suggesting the In： Fe：Mn：LN crystals are excellent holographic storage materiel with better synthetical properties than Fe：Mn：LN crystals.

The Effect of Oxidation/Reduction Disposing on Optical Properties of Mg:Fe:Mn:LiNbO_3 Crystals

The congruent tri-doped Mg:Mn:Fe:LiNbO 3 crystal has been grown by Czochralski method. Some crystal samples are reduced in Li 2CO 3 powder at 500 ℃ for 24 hours or oxidized for 10 hours at 1100 ℃ in Nb 2O 5 powder. Compared with As-grown Mg:Mn:Fe:LiNbO 3, the absorption edge in UV-Vis. absorption spectrum of the oxidized sample and the reduced shifts to the violet and the red, respectively. Reduction increases the absorption of crystals in visible light region. In two-wave coupling experiments, the writing time, maximum diffraction efficiency and the erasure time of crystal samples in the same conditions are determined. The results indicate that oxidation and reduction disposing has great effect on the holographic recording properties of these crystals. The reduced crystal exhibits the fastest response time of 160 s among the crystal series. The mechanism of post-disposing effect on the holographic recording properties of Mg:Mn:Fe:LiNbO 3 crystals are investigated.

Zn∶Fe∶LiNbO_3晶体全息存储性能研究

以提拉法生长Zn(1mol% )∶Fe∶LiNbO3,Zn(4mol % )∶Fe∶LiNbO3,Zn(7mol% )∶Fe∶LiNbO3晶体 Zn∶Fe∶LiNbO3晶体随着Zn2 + 浓度的增加 ,抗光致散射能力增加 ,Zn(7mol% )∶Fe∶LiNbO3晶体抗光致散射能力比Fe∶LiNbO3晶体提高两个数量级以上 测试了Zn∶Fe∶LiNbO3晶体衍射效率、响应时间 以Zn(7mol % )∶Fe∶LiNbO3晶体作为存储元件 ,Zn(4mol% )∶Fe∶LiNbO3晶体作为位相共轭镜 ,进行全息关联存储试验 试验结果显示出成像质量好、图像清晰完整、噪音小等优点 研究了Zn∶Fe∶LiNbO3晶体全息存储性能增强的机理 Zn(4mol% )

Eu∶Zn∶LiNbO_3晶体全息存储性能的研究

在ＬｉＮｂＯ３中掺进Ｅｕ２Ｏ３和ＺｎＯ生长Ｅｕ∶Ｚｎ∶ＬｉＮｂＯ３晶体。采用二波耦合光路测试晶体的指数增益系数和衍射效率。以Ｅｕ∶Ｚｎ∶ＬｉＮｂＯ３晶体作为存储元件，实现了全息关联存储。

Zn∶Fe∶LiNbO_3晶体的生长及位相共轭效应的研究

在ＬｉＮｂＯ３中掺进ＺｎＯ和Ｆｅ２Ｏ３生长出Ｚｎ∶Ｆｅ∶ＬｉＮｂＯ３晶体。测试了晶体抗光致散射能力、位相共轭反射率和响应时间。研究了Ｚｎ∶Ｆｅ∶ＬｉＮｂＯ３位相共轭效应增强的机理。

激光晶体Zn∶Ho∶LiNbO_3的生长及其光学性能

在生长ＬｉＮｂＯ３晶体过程中掺进ＺｎＯ和Ｈｏ２Ｏ３，生长出Ｚｎ∶Ｈｏ∶ＬｉＮｂＯ３晶体。测试了Ｚｎ∶Ｈｏ∶ＬｉＮｂＯ３晶体的双折射梯度、光损伤阈值、吸收光谱和荧光光谱。研究表明，Ｚｎ∶Ｈｏ∶ＬｉＮｂＯ３晶体是优良的激光介质材料。

Zn∶Fe∶LiNbO_3晶体的生长及其全息性能的研究

本文首次详细报导了Ｚｎ∶Ｆｅ∶ＬｉＮｂＯ３晶体的生长技术，研究了晶体的吸收光谱、衍射效率和响应时间。与Ｆｅ∶ＬｉＮｂＯ３相比，Ｚｎ∶Ｆｅ∶ＬｉＮｂＯ３晶体响应速度快，且衍射效率较高，并具有较宽的角度响应范围，是一种优良的全息记录介质材料。

Zn∶Er∶LiNbO_3单晶的坩埚下降法生长及光谱特性

报道了Zn:Er:LiNbO3单晶的坩埚下降法生长工艺. 通过控制晶体生长固液界面的温度梯度(30～35 ℃·cm-1)、晶体的生长速度(0.8～1.5 mm·h-1)、密闭Pt坩埚等条件生长了宏观无缺陷的Zn2+(3%)和Er3+(0.6%)共掺的LiNbO3单晶. 用X射线衍射(XRD)和差热分析(DTA)表征了获得的晶体, 并测量了晶体不同部位的吸收光谱和荧光谱. 从吸收光谱以及由XRD数据计算所得的晶胞参数推断, 沿生长方向Er3+在晶体中的浓度分布逐步减少. 光谱数据表明, 晶体底部样品的吸收强度和荧光强度要比顶部大, 而对应于Er3+上能级4S3/2和2H11/2跃迁至基态4I15/2的绿光发射, 晶体底部却比顶部表现出更高的上转换效率. 从晶体的内部结构、缺陷情况以及Er3+的分凝现象解释了产生上述现象的内在机制.

Zn∶Mg∶LiNbO_3抗光折变性能机理的研究

LiNbO 3crystal possesses electro optic effect and nonlinear optical effect.Bec ars e it is easy to generate photo damage(photorefractive) for LiNbO 3.This limits i ts application in some fields.When doping 6mol% ZnO or 5mol% MgO in LiNbO 3 cry stal to grow Zn∶LiNbO 3 or Mg∶LiNbO 3 crystal,the photo damage resistance ab ility fo these two crystals is two orders of magnitude higher than that of LiNbO 3.We doped 3mol% ZnO and 3mol% MgO to grow Zn∶Mg∶LiNbO 3 crystal and used Fourier spectrophotometer to measure the infrared transmission spectra.The waven umber range to measure the OH - stretched vibration transmission spectra of Zn ∶LiNbO 3,Mg∶LiNbO 3 and Zn∶Mg∶LiNbO 3 crystal is 3200 4000cm -1 .The measurement result is that the OH - stretched vibration absorption peak of Zn( 6mol%):LiNbO 3,Mg(5mol%):LiNbO 3 and Zn(3mol%):Mg(3mol%):LiNbO 3 crystal is at 3535cm -1 (2.83μm),while that of pure LiNbO 3,Zn(3mol%):LiNbO 3 and M g(3mol%):LiNbO 3 is at 3484cm -1 (2.87μm).We take the direct obseration me thod of the focula distortion in crystal to measure the photorefractive threshol d value of these crystals and gained the result that the photorefractive thresho ld value of Zn(6mol%):LiNbO 3,Mg(5mol%):LiNbO 3 and Zn(3mol%):Mg(3mol%):LiNbO 3 increase above two orders of magnitude higher than pure LiNbO 3 crystal and the photorefractive threshold value of Zn(3mol%):LiNbO 3 and Mg(3mol%):LiNbO 3 is a little higher than that of pure LiNbO 3 crystal.The congruent compositio n ratio of LiNbO 3 is Li/Nb=0.946.A part of Nb 5+ take place Li + site to form the intrinsic defect antisite Nb 4+ Li .The charge transport proc ess in LiNbO 3 is due to this kind of intrinsic defect.Especially in high light intensity,the intrinsic defect is important.The quantity that make antisite Nb 4+ Li defect structure disappear when doping ions (Mg 2+ and Zn 2+ ) substitute for all Nb 4+ Li at Li + site is called the thre shold concentration for this impurity ion.At the same time the impurity ion star t to take place Nb site.The photo damage resistance impurity ion is to drive ant i site Nb Li from Li site to normal Nb site so that the OH - absorption peak shifts to 2.83μm from 2.87μm.The fact that the OH - absorption peak of Zn(3m ol%):Mg(3mol%):LiNbO 3 crystal shifts to 2.83μm from 2.87μm and its photo dam age resistance threshold value is two orders of magnitude higher than pure LiNbO 3 crystal shows that above analyse is reasonable.