Lu^(3+)掺杂Na_(5)Y_(9)F_(32)∶Ho^(3+)/Yb^(3+)/Ce^(3+)单晶体的增强红色上转换发光与光学温度传感性能

采用密封的坩埚下降法技术生长了一系列Lu^(3+)(摩尔分数0、0.6%、1.2%、1.8%)掺杂Na_(5)Y_(9)F_(32)∶Ho^(3+)/Yb^(3+)/Ce^(3+)单晶体。在980 nm LD激发下,观察到单晶体的绿光543 nm(^(5)S_(2)/^(5)F_(4)→^(5)I_(8))、红光656 nm(^(5)F_(5)→^(5)I_(8))以及近红外750 nm(^(5)S_(2)/^(5)F4→^(5)I_(7))上转换发光。从上转换发光强度随激发光强度的变化情况,确定了543 nm、656 nm与750 nm的发光为双光子跃迁过程。研究了Lu^(3+)离子掺杂浓度对其发光强度与荧光寿命的影响情况,随着Lu^(3+)掺杂浓度从0增加到1.8%,单晶体中的656 nm红光逐步增强,543 nm绿光与750 nm近红外光随之减弱,红绿光强度比从0.01增加到了1.55,而543 nm荧光寿命从1.29 ms降低至0.99 ms。Lu^(3+)离子的掺入取代Y^(3+)晶格位,改变了单晶体的局域场环境,导致上转换发光强度的变化。基于随温度变化的上转换红光656 nm(^(5)F5→^(5)I8)与绿光543 nm(^(5)S_(2)/^(5)F4→^(5)I8)的发光强度变化,研究了1.8%Lu^(3+)掺杂Na_(5)Y_(9)F_(32)∶Ho^(3+)/Yb^(3+)/Ce^(3+)单晶体在298~448 K范围内的绝对灵敏度和相对灵敏度最大值分别为0.242%·K^(-1)和0.217%·K^(-1)。

基于WS_2可饱和吸收体的调Q锁模Tm,Ho:LLF激光器

采用聚乙烯醇塑料膜为基质的WS_2作为可饱和吸收体,在Tm,Ho:LiLuF_4全固态激光器中实现了被动调Q锁模运转.以掺钛蓝宝石激光器作为抽运源,当最大吸收抽运功率为2.6 W时,激光输出功率为156 mW,典型的调Q脉冲包络重复频率为25 kHz,脉宽约为300μs.当吸收功率大于1.39 W时,进入稳定调Q锁模运转,对应锁模脉冲序列的重复频率为131.6 MHz,调整深度接近100%.结果表明:WS_2可以作为2μm波段全固态激光器锁模的吸收体材料.

高单脉冲能量被动调Q锁模Tm,Ho:LLF激光器

报道了一种采用氧化石墨烯作为可饱和吸收体的二极管泵浦的被动调Q和调Q锁模运转的Tm, Ho:LLF激光器。采用透过率分别为3%、5%和9%的输出镜,首先研究了Tm, Ho:LLF激光器的连续运转特性。实验和模拟结果均表明采用透过率为9%的输出镜输出特性最好,当最大泵浦功率为20 W时,连续光输出功率高至1 793 mW。接着以氧化石墨烯为饱和吸收体,采用透过率为9%的输出镜研究了Tm, Ho:LLF激光器的调Q和调Q锁模特性。实验表明:当790 nm LD泵浦功率小于7.26 W时,激光处于单纯调Q运转状态;当大于7.26 W时,激光器进入稳定的调Q锁模状态,当最大泵浦功率为20 W时,最大输出功率为1 052 mW,锁模重复频率为53.19 MHz,对应的平均单脉冲能量为19.77 nJ,该单脉冲能量是目前2μm锁模激光器的最高指标,同时证实了氧化石墨烯材料在大能量高功率激光锁模中是发展潜力优良的二维锁模材料。

Yb,Ho∶GdScO_(3)晶体生长及光谱性能分析

采用提拉法生长出了尺寸为∅30 mm×50 mm的Yb,Ho∶GdScO_(3)晶体。通过X射线衍射得到了晶体的粉末衍射数据,使用GSAS软件进行了全谱拟合,得到了晶体的结构参数。测试了晶体的拉曼光谱,在100~700 cm^(-1)观察到18个拉曼振动峰。对Yb,Ho∶GdScO_(3)晶体的光谱特性进行了表征,并计算了Yb^(3+)的吸收截面,其在940、975 nm处的吸收截面分别为0.31×10^(-20)、0.42×10^(-20) cm^(2)。采用Judd-Ofelt理论计算了Ho^(3+)的跃迁强度参量Ω_(t),Ω_(4)/Ω_(6)值为2.04,并计算了辐射跃迁概率、能级寿命及荧光分支比等光谱参数。结果表明,Yb,Ho∶GdScO_(3)晶体的发光性能良好,是一种有前景的2~3μm激光晶体候选材料。

Spectroscopic properties of heavily Ho^(3+) -doped barium yttrium fluoride crystals

The 30 at.% Ho： BaY2F8 crystals were grown by the Czochralski method, and their spectroscopic properties are analyzed systematically by standard Judd–Ofelt theory. The Judd–Ofelt intensity parameters are estimated to be Ω2 =6.74 × 10^-20cm^2,Ω4 = 1.20 × 10^-20cm^2, and Ω6= 0.66 × 10^-20cm^2, and the fluorescence branching ratios and radiative lifetimes for a series of excited state manifolds are also determined. The emission cross sections with our measured infrared luminescence spectra, especially important for 4.1 μm, are calculated to be about 4.37 × 10^-21cm^2. The crystal quality is preliminarily tested through a mid-infrared laser emission experiment.

Upconversion Luminescence from Ho3＋ and Yb3＋ Codoped α-NaYF4 Single Crystals

The Ho3＋/yb3＋ co-doped a-NaYF4 single crystal was grown successfully for the first time by a modified Bridgman method in which KF was used as assisting flux and a large temperature gradient （70-90℃ /cm） of solid-liquid interface was adopted. Upconversion emissions at green -544 nm, red -657 and -751 nm were obtained under 980 nm laser diode excitation. The intensity at -544 nm was much stronger than those of -657 and -751 nm. The mechanisms of the upconversion emissions were investigated by studying the relationship between the upconversion intensity and pump power. The optimized Yb3＋ concentration was about 8.08moi% when Ho3＋ concentration was hold at about 1.0mol%. The results showed that Ho3＋/yb3＋ doped α-NaYF4 single crystal was a possible candidate upconversion material for the green solid-state laser.

Crystal Structure and Spectroscopic Properties of a New Ternary Tungstate Li_3Ba_2Ho_3(WO_4)_8

A single crystal of Li3Ba2Ho3（WO4）8 was obtained from a flux of Li2WO4 under an air atmosphere. The structure of the pure crystal was determined by single-crystal X-ray diffraction method. It crystallizes in the monoclinic system, space group C2/c with a = 5.240（4）, b = 12.790（10）, c = 19.247（15）, β = 91.921（15）°, V = 1289.1（18）3, Z = 2, Mr = 2773.09, Dc = 7.144 g/cm3, μ = 47.732 mm-1, Rint = 0.0693, F（000） = 2340, the final R = 0.0472 and wR = 0.1221 for 1535 observed reflections （I 2σ（I））. The Li3Ba2Ho3（WO4）8 has a high structure disorder with one 8f site shared by Li（1） and Ho ions with occupancy of 0.25 and 0.75, respectively. The fundamental structure is constituted by distorted square antiprisms Ho/Li（1）O8 with C1 symmetry, distorted Li（2）O6 octahedra and BaO10 polyhedra. The optical properties were investigated by IR and absorption spectroscopy, and the emission cross sections and gain cross sections of 5I7 → 5I8 of Ho3＋ were calculated.

2.0-μm emission and energy transfer of Ho^(3+)/Yb^(3+) co-doped LiYF_4 single crystal excited by 980 nm

Ho3＋/yb3＋ co-doped LiYF4 single crystals with various Yb3＋ concentrations and ,-~ 0.98 mol% Ho3＋ concentration are grown by the Bridgman method under the conditions of taking LiF and YF3 as raw materials and a temperature gradient （40 ~C/cm-50 ~C/cm） for the solid-liquid interface. The luminescent performances of the crystals are investigated through emission spectra, infrared transmittance spectrum, emission cross section, and decay curves under excitation by 980 nm. Compared with the Ho3＋ single-doped LiYF4 crystal, the Ho3＋/yb3＋ co-doped tiYf4 single crystal has an obviously enhanced emission band from 1850 nm to 2150 nm observed when excited by a 980-nm diode laser. The energy transfer from Yb3＋ to Ho3＋ and the optimum fluorescence emission around 2.0 p-m of Ho3＋ ions are investigated. The maximum emission cross section of the above sample at 2.0 p.m is calculated to be 1.08 × 10-20 cm2 for the LiYF4 single crystal of 1-mol% Ho3＋ and 6-mo1% Yb3＋ according to the measured absorption spectrum. The high energy transfer efficiency of 88.9% from Yb3＋ to Ho3＋ ion in the sample co-doped by Ho3＋ （1 mol%） and Yb3＋ （8 tool%） demonstrates that the Yb3＋ ions can efficiently sensitize the Ho3＋ ions.

基于单壁碳纳米管调Q锁模低阈值Tm,Ho:LiLuF_4激光器

采用垂直生长法制作的单壁碳纳米管作为可饱和吸收体,结合特殊的低阈值谐振腔设计,首次在Tm,Ho:LiLuF_4全固态激光器中实现了低阈值自启动被动调Q锁模运转.以波长可调的掺钛蓝宝石固体激光器作为抽运源,选用1.5%,3%和5%的输出耦合镜,获得了出光阈值低至52,59和62mW的连续光输出.采用3%输出耦合镜,获得了阈值低至250mW的稳定调Q锁模脉冲输出,调Q包络的脉宽为2μs,调Q包络下锁模脉冲重复频率178.6MHz,最大输出功率154mW,最大的单脉冲能量为0.86nJ,调制深度接近100%.

室温下Ho∶YAG激光器输出3J的2．1μm激光

根据对２．１μｍ波长Ｃｒ，Ｔｍ，Ｈｏ∶ＹＡＧ激光器的实验研究，详细分析了冷却温度。

Tm,Ho：BaY2F8晶体光谱性能与能量传递

采用提拉法,生长钬铥双掺氟化钇钡[分子式:Tm3+,Ho3+∶BaY2F8,简称Tm,Ho∶BYF]激光晶体。工艺参数:拉速0.5 mm.h-1,转速5 r.min-1,冷却速率10℃.h-1。XRD表明:属于单斜晶系,空间群C12/m1。计算出晶格参数:a=0.69973 nm,b=1.05293 nm,c=0.427 84 nm,β=99.71°。测试了晶体的吸收及荧光光谱,同时计算了784 nm处吸收峰的半高宽、吸收系数及吸收截面,分别为3.2 nm,2.23 cm-1,7.44×10-21 cm2。该吸收峰对应于Tm3+离子从基态3H6到激发态3H4的跃迁。Tm,Ho∶BYF晶体在2.06μm附近有很强的荧光发射峰,在该荧光峰的发射截面和荧光寿命分别为4.96×10-21 cm2,10.1 ms。Tm3+→Ho3+的正向、反向能量转换系数之比是10.4。

光纤耦合二极管端泵2μm CW双掺Tm,Ho∶GdVO_4激光器

同YLF和YAG基质相比,在TmHo∶GdVO4晶体中Tm3+离子在800nm附近有非常强的和宽的吸收带,所以该晶体非常适合商品化的GaAlAs激光二极管泵浦.在液氮制冷晶体条件下,利用光纤耦合激光二极管及消色差光学耦合系统端面泵浦双掺5%Tm,0.5%Ho∶GdVO4晶体,在泵浦功率14W、泵浦波长794nm时,实现了2.048μm激光输出,连续运转输出功率3.6W,相应的光光转换效率为25.7%,斜率效率26.6%.相对于吸收的泵浦功率,光光转换效率为35%.由于Tm3+离子间的交叉弛豫效应,泵浦量子效率达到1.3.

Ho:YVO_4晶体中Ho^(3+)光谱参数的计算

根据Ho3+在Ho :YVO4 晶体的吸收谱和 0 6～ 2 1μm波段的荧光谱 ,用J O理论计算了Ho3+的强度参数Ωλ ,并由此计算了激发能级的振子强度、自发辐射跃迁几率、荧光分支比和积分发射截面等光谱参数 ,讨论了Ho :YVO4 晶体作为红外激光材料的可能性。

[Ho_2(phen)_4(H_2O)_4(OH)_2](phen)_2(NO_3)_4的合成、晶体结构及磁性

在甲醇与水的混合溶剂中 ,经浓硝酸硝化的Ho2 O3 与 1,10 邻菲啉反应形成氢氧根桥联的双核钬配合物[Ho2 (phen) 4(H2 O) 4(OH) 2 ](phen) 2 (NO3 ) 4(phen =1,10 邻菲啉 ) .单晶X射线衍射晶体结构测定表明晶体属三斜晶系 ,P 1(no .2 )空间群 ,晶胞参数a =1.12 41(1)nm ,b =1.1439(1)nm ,c =1.40 5 8(1)nm ,α =93.989(7)°,β =98.173(7)° ,γ =10 8.19(1)°,V =1.6 874(4 )nm3 ,Z =1,Dc=1.737g/cm3 ,F(0 0 0 ) =880 ,775 2个独立衍射点中 ,5 70 2个可观测点满足Fo2 ≥ 2σ(Fo2 ) ,R1=0 .0 499,wR2 =0 .0 85 8.标题配合物由中心对称的双核 [Ho2 (phen) 4(H2 O) 4 (OH) 2 ]4 + 配阳离子 ,邻菲啉phen分子及硝酸根NO-3 阴离子组成 .每个稀土原子与 2个邻菲啉配体 ,2个水分子和 2个氢氧根配位形成配位数为 8的 [HoN4 O4 ]四方反棱柱 .配位多面体通过两氢氧根基团形成共棱的 [Ho2 N8O6]双四方反棱柱 [d(Ho—N) =0 .2 5 49～ 0 .2 5 6 5nm ,d(Ho—OH2 O) =0 .2 35 6 ,0 .2 36 6nm ,d(Ho—OOH) =0 .2 2 2 3,0 .2 2 40nm].通过氢键和芳环堆积作用 ,配阳离子和邻菲啉分子排列形成平行于 (10 1)的两维层结构 ,NO-3 阴离子位于层之间 .标题配合物为顺磁物质 ,在 5～ 30 0K区间内遵循Curie Weiss定律 ?

Cr,Yb,Ho:YAGG可调谐激光晶体生长及开裂研究

本文采用提拉法生长了Cr，Yb，Ho：YAGG可调谐激光晶体，并从理论上讨论了热应力、提拉速度、晶体转速和降温速率等因素对晶体开裂的影响，最后给出了掺铬、镱和钬钇铝镓石榴石激光晶体生长的最佳工艺条件：温度梯度为0．5℃／mm，提拉速度1-2mm／h，晶体转速20-40r／min，冷却速率不超过20℃／h。

2．1μm波长Cr，Tm，Ho∶YAG激光器的进展

根据国内外的文献资料对２．１μｍ波长Ｃｒ，Ｔｍ。

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。

准四能级双掺Tm/Ho钒酸钆激光器

在考虑两种离子发光的动力学进展基础上,描述了2μm双掺铥钬(Tm/Ho)系统Tm→Ho能量转移基本过程,建立双掺Tm/Ho系统准四能级速率方程,得出阈值抽运功率和斜率效率的表达式,并利用得出的结论去分析在液氮制冷下光纤耦合激光二极管(LD)端面抽运掺铥钬钒酸钆(Tm/Ho∶GdVO4)激光器实验。通过实验,实现了2μm Tm/Ho∶GdVO4激光器的运转,在抽运功率14W时,激光输出功率3.5W,光-光转换效率25%,阈值抽运功率838mW,理论和实验有很好的一致性。同时也对实验中观测到的上转换绿荧光现象进行了定性的分析。

Cr,Tm,Ho∶YAG中Tm→Ho的能量转移

本文采用Boltzmann分布近似 ,计算了不同温度下Tm→Ho的净能量转移 ;计算了实验中不同温度下Ho3 + 离子的荧光发射强度在整个Tm—Ho体系荧光发射中的比例。我们的实验和计算表明 ,对Tm—Ho准三能级体系采用Boltzmann分布近似 。

Li/Nb变化对Mg:Ho:LiNbO_3晶体光学性能的影响

采用提拉法生长了不同Li/Nb(Li/Nb=0.94,1.05,1.20 and 1.38)的Mg:Ho:LiNbO3单晶.测试了Mg:Ho:LiNbO3晶体的双折射梯度和抗光损伤能力.实验结果表明:Li/Nb=1.38的Mg:Ho:LiNbO3晶体有较好的光学均匀性,随着Li/Nb比的增加,晶体抗光损伤能力增强,并分析了其抗光损伤能力增强的机理.结合LiNbO3晶体的锂空位缺陷模型和占位机制解释了相关实验结果.