N^＋(N=Li,Na,K)对发光材料M3(M=Ca,Sr,Ba)Y2(BO3)4：Eu^3＋光谱的影响

采用高温固相反应方法在空气中制备了M3(M=Ca,Sr,Ba)Y2(BO3)4∶Eu3+红色发光材料,测量结果显示,材料的主发射峰均位于613 nm处,监测613 nm发射峰时,所得材料的激发光谱相同。研究了Li+,Na+和K+对M3(M=Ca,Sr,Ba)Y2(BO3)4∶Eu3+材料激发与发射光谱的影响,结果显示,加入Li+,Na+和K+后,M3(M=Ca,Sr,Ba)Y2(BO3)4∶Eu3+材料的激发与发射光谱的峰值位置并不发生变化,但材料的激发与发射光谱的峰值强度均得到了不同程度的增强。在Li+,Na+和K+掺入浓度相同的条件下,研究发现,与加入Na+和K+时相比,加入Li+时,M3(M=Ca,Sr,Ba)Y2(BO3)4∶Eu3+材料的激发与发射光谱的峰值增强效果最明显。进而研究了Sr3Y2(BO3)4∶Eu3+材料发射峰强度随Li+掺杂浓度的变化情况,结果表明,随着Li+掺杂浓度的增大,Sr3Y2(BO3)4∶Eu3+材料发射峰强度先增大后减小,在Li+浓度为5 mol%时到达峰值,约为未掺杂时的两倍。

柠檬酸燃烧法制备Sr_3Y_2(BO_3)_4:Eu^(3+)荧光粉及特性研究

以柠檬酸为络合物及助燃剂,使用简单的凝胶燃烧法,通过调整B2O3用量,制备出了不同含量Eu3+掺杂的Sr3 Y2(BO3)4基红光荧光粉。对所得样品进行了X射线衍射分析(XRD)、差热分析(DTA),扫描电镜分析(SEM)及荧光光谱分析(FDS)。分析结果显示,样品的烧结温度比固相法降低了100℃,且其粉体的分散性和颗粒度都得到了改善,并且得到Eu3+最佳的掺杂浓度为12mol%。

Nd^(3+)掺杂的Sr_3Y_2(BO_3)_4晶体光谱特性研究

采用提拉法生长出25mm×40mm的Nd3+∶Sr3Y2(BO3)4晶体,测试了该晶体的吸收光谱、荧光光谱及荧光寿命。结果表明:Nd3+∶Sr3Y2(BO3)4晶体在807nm附近有最强的吸收峰,其半峰宽(FWHM)为16nm,宽的吸收半峰宽适合于LD泵浦;从荧光光谱得到发射波长分别为910.8nm、1065.2nm和1399nm的荧光峰。根据吸收和荧光光谱,计算了晶体的吸收截面和发射截面。采用J-O理论计算了Nd3+在Sr3Y2(BO3)4中的强度参数、各能级的振子强度、自发辐射几率、荧光分支比等参数。计算结果表明,其强度参数Ω2=3.816×10-20cm2,Ω4=10.895×10-20cm2,Ω6=12.44×10-20cm2,辐射寿命为104μs,量子效率η=49.7%,荧光分支比β1(0.88μm)=0.429,β2(1.06μm)=0.461,β3(1.35μm)=0.107,β4(1.88μm)=0.003。

双掺Er^(3+)/Yb^(3+)∶Sr_3La_2(BO_3)_4晶体的生长与光谱特性

采用提拉法生长了尺寸为20mm×30mm的Er3+/Yb3+∶Sr3La2(BO3)4晶体,研究了Er3+/Yb3+∶Sr3La2(BO3)4晶体的吸收光谱和荧光光谱。根据Judd-Ofelt理论分析并计算了辐射跃迁几率、辐射寿命、荧光分支比等光谱参数,获得的唯象参数为:Ω2=15.59×10-20cm2,Ω4=2.25×10-20cm2,Ω6=1.49×10-20cm2。在Er3+/Yb3+∶Sr3La2(BO3)4晶体中Er3+在1533nm处发射跃迁截面为7.88×10-21cm2,Er3+的4I13/2→4I15/2能级跃迁的荧光寿命和辐射寿命分别为0.728ms和4.24ms,结果表明Yb3+对Er3+有敏化作用,提高了对泵浦光的吸收能力,Er3+/Yb3+∶Sr3La2(BO3)4晶体可望作为1.55μm波段的一种有潜力的激光材料。

Er^3＋／Yb^3＋：Sr3Y2(BO3)4晶体的光谱和激光性质

采用提拉法生长了双掺Yb3+和Er3+离子浓度分别为18.63%和0.87%(原子分数)的Sr3Y2(BO3)4晶体。利用测量的偏振吸收谱结合Judd-Ofelt理论,拟合得到了该晶体中Er3+离子的偏振和有效J-O参数。测量了Er3+离子4I13/2能级和Yb3+离子2F5/2能级的荧光衰减曲线,并计算了4I13/2能级的荧光量子效率和Yb3+到Er3+的能量传递效率。利用Fuchtbauer-Ladenberg公式计算了Er3+离子4I13/2→4I15/2跃迁的偏振受激发射截面。在平-凹谐振腔中,利用970 nm波长光纤耦合准连续半导体激光端面泵浦1.12 mm厚的该晶体,当输出镜透过率为1.5%时,获得了最大输出功率为1.3 W和斜率效率为20%的1560 nm附近的激光输出。结果表明,Er3+/Yb3+:Sr3Y2(BO3)4晶体是一种优良的1.5～1.6μm波段激光的增益介质。

Ln_7O_6(BO_3)(PO_4)_2∶Eu(Ln=La,Gd,Y)的VUV-UV激发和辐射发光

本文报道了Ln7O6(BO3) (PO4 ) 2 ∶Eu(Ln =La ,Gd ,Y)在VUV UV区的激发光谱及Eu3 + 在可见区的发射光谱。其激发光谱包括基质在真空紫外区的激发带和激活剂离子在紫外区的Eu3 + O2 -电荷迁移带 ,随La3 + ,Gd3 + ,Y3+ 离子半径逐渐减小 ,Eu3 + O2 -电荷迁移带的重心位置逐渐向高能量方向移动 ,Gd7O6(BO3) (PO4 ) 2 ∶Eu和Y7O6(BO3) (PO4 ) 2 ∶Eu在真空紫外区的吸收与Eu3+ O2 -电荷迁移带位于紫外区的吸收的比值要高于在La7O6(BO3) (PO4 ) 2 ∶Eu中的这个比值。激发能可被基质吸收 ,传递给激活剂离子 ,得到Eu3 + 的红光发射。在Gd7O6(BO3) (PO4 ) 2 ∶Eu中 ,5D0 →7F1的发射强度较强 ,在Y7O6(BO3) (PO4 ) 2 ∶Eu中 ,5D0→7F2 和5D0 →7F3的跃迁较强。

Nd^(3＋)：Sr_3Gd_2(BO_3)_4晶体的光谱特性研究(英文)

用提拉法成功生长出Nd:Sr3Gd2(BO3)4晶体,并对其光谱性能进行了研究.测量了晶体在200～1000nm波段的吸收谱.用808nm的波长激发,测量了晶体的荧光光谱和荧光寿命,计算得到晶体的发射截面.根据J-O理论计算了晶体的光谱参数,与其它Nd掺杂的晶体的光谱参数做了比较和分析.

Growth and Spectroscopic Properties of Nd^(3+):Sr_3Gd_2(BO_3)_4 Crystal

This paper reports the growth, X-ray diffraction and spectroscopy of Nd3＋：Sr3Gd2（BO3）4 crystal. A Nd3＋：Sr3Gd2（BO3）4 crystal with dimensions of φ20 × 45 mm3 has been grown by the Czochralski method. Nd3＋：Sr3Gd2（BO3）4 crystal belongs to the orthorhombic system, space group Pnma （D2h） with a = 0.7401, b = 1.604 and c = 0.8755 nm. The absorption and emission spectra of Nd3＋：Sr3Gd2（BO3）4 were investigated. The absorption cross section oa is 3.11 × 10^-20cm2 at 808 nm. The absorption transition at 808 nm has an FWHM of 14 nm. The luminescence lifetime τf is 51.7 μs. The emission cross section oc at 1064 nm wavelength is 1.09 × 10^-19 cm2.

Growth and Structure of Sr_3Yb_2(BO_3)_4 Crystal

A Sr3Yb2（BO3）4 single crystal was obtained by the Czochralski method. The structure of Sr3Yb2 （BO3）4 crystal was determined by single-crystal X-ray diffraction. The compound crystallizes in orthorhombic, space group Pnma with a=7.3750（8）, b=15.9265（14）, c=8.6776（9）, V=1019.25（18）3 , Mr=844.18, Z=4, Dc=5.501 g/cm3 , λ（MoKa）=0.71073, μ= 33.835 mm-1 , F（000）=1480, the final R=0.0339 and wR=0.0907 for 1090 observed reflections with I〉2σ（I）. The structure features a three-dimensional framework composed of isolated BO3 planar triangles bridged by YbO8 and SrO8 polyhedra. The Sr2＋ and Yb3＋ occupy statistically three independent sites with a Cm and two C1 local symmetries.

Luminescent characteristics of Ba_3Y_2(BO_3)_4:Eu^(3+) phosphor for white LED

The Ba3Y2（BO3）4：Eu^3＋ phosphor was synthesized using a high temperature solid-state reaction method and the luminescent characteristics were investigated. The emission spectrum exhibited one strong red emission at 613 nm, corresponding to the electric dipole 5D0-TF2 transition of Eu^3＋, under 365 nm excitation. The excitation spectrum of 613 nm indicated that the Ba3Y2（BO3）n：Eu^3＋ phosphor was effectively excited by ultraviolet （UV） （254, 365 and 400 nm） and blue （470 nm） light. The effect of Eu^3＋ concentration on the 613 nm emission of the Ba3Y2（BO3）n：Eu^3＋ phosphor was measured. The results showed that the emission intensity increased with increasing Eu^3＋ concentration, and then decreased. The CIE color coordinates of Ba3Y2（BO3）4：Eu^3＋ phosphor were x=0.641 and y=0.359 at 15 mol.% Eu^3＋.

Sr_2CeO_4/Ln^(3+)(Ln=Er,Ho,Tm)的微波合成与荧光性质

首次采用微波法合成了Sr2CeO4/Ln3+(Ln=Er,Ho,Tm)荧光体.研究了样品的荧光性质,并观察到Er3+,Ho3+,Tm3+掺杂的Sr2CeO4材料的上转换发光现象.荧光光谱证实,存在基质Sr2CeO4向稀土离子Ln3+的能量传递.

Luminescence characteristics of Eu^(3+) activated borate phosphor for white light emitting diode

In this paper, the Sr3Y2 （BO3）4 ：Eu^3＋ phosphor was synthesized by high temperature solid-state reaction method and the luminescence characteristics were investigated. The emission spectrum exhibits one strong red emission at 613 nm corresponding to the electric dipole 5^Do-7^F2 transition of Eu^3＋ under 365 nm excitation, this is because Eu^3＋ substituted for Y^3＋ occupied the non-centrosymmetric position in the crystal structure of Sr3Y2（BO3）4. The excitation spectrum indicates that the phosphor can be effectively excited by ultraviolet （254 nm, 365 nm and 400 nm） and blue （470 nm） light. The effect of Eu^3＋ concentration on the red emission of Sr3Y2（BO3）4 ：Eu^3＋ was measured, the result shows that the emission intensities increase with increasing Eu^3＋ concentration, then decrease. The Commission Internationale del＇Eclairage chromaticity （x, y） of Sr3Y2（BO3）4 ：Eu^3＋ phosphor is （0.640, 0.355） at 15 mol% Eu^3＋.

Tm^(3+):Sr_3Y_2(BO_3)_4晶体光谱特性的研究

生长了掺Tm3+离子Sr3Y2(BO3)4晶体,并对其光谱性能进行了研究.应用J-O理论分析并计算了线性强度振子与唯象参数,得到唯象参数Ω2、Ω4和Ω6值分别为2.691×10-20、2.432×10-20和1.287×10-20cm2.采用RM法,计算了Tm3+:Sr3Y2(BO3)4晶体3F4→3H6跃迁的发射截面,并讨论了该晶体在近红外波段的增益截面与粒子数反转率间的关系.与其它掺Tm3+晶体相比,Tm3+:Sr3Y2(BO3)4晶体有较大的发射截面和较宽的调谐范围.

高分子网络凝胶法制备纳米SrCe_(0.90)Y_(0.10)O_(2.95)粉体

丙稀酰胺为单体,N,N'-亚甲基双丙稀酰胺为网络剂,通过高分子网络法制备固体电解质纳米SrCe0.90Y0.10O2.95粉体,制得粉体粒度范围在31～50 nm.利用X-射线衍射测定其结构,通过透射电镜测量其形貌.由红光谱可以得知粉体中的网络剂和单体在450℃以上才能完全分解,通过X-射线衍射可以知道在650℃时主要合成了Ce2Y2O7、Ce2Sr2O5、和CeO2三相,在1000℃时已经基本形成较完整的晶体结构.

近紫外激发单一白光荧光粉Sr_3Y_2(GeO_4)_3∶Dy^(3+)的制备及其发光特性

采用高温固相法制备了Sr3Y2(GeO4)3∶Dy3+荧光粉,利用X射线粉末衍射、荧光光谱等分析手段对荧光粉样品进行了表征,分析了其发光特性.讨论了Dy3+离子掺杂浓度以及添加不同助熔剂对Sr3Y2(GeO4)3∶Dy3+荧光粉发光强度的影响,并计算了发光材料的色坐标.研究结果表明,样品在388nm近紫外光激发下发射出强烈的蓝光(481nm)和黄光(573nm);Dy3+浓度影响其发光强度,随着Dy3+浓度的增大,荧光强度增强明显,色坐标越接近纯白光色坐标(0.33,0.33);当Dy3+浓度达到12%时,样品的荧光强度最强,色坐标为(0.32,0.33).

掺镱飞秒激光晶体研究进展

飞秒激光在军事、医学、通讯、加工等领域有着重要应用,已经成为新世纪激光技术领域的研究热点。得益于激光二极管(LD)的快速发展,以LD作为泵浦源成为新型全固态飞秒激光器的发展趋势。Yb^3+离子掺杂的激光晶体材料因其独特的能级结构、宽带吸收与发射等优势,逐渐成为LD直接泵浦并实现1.0μm飞秒激光输出的重要增益介质。详细总结了当前掺Yb^3+飞秒激光晶体的研究进展,分析了目前存在的主要问题,给出了未来飞秒激光晶体发展的两个建议方向:高效率小功率飞秒激光和大功率高能量飞秒激光。以Yb^3+:Sr3Y2(BO3)4晶体为例,详细研究了其晶体生长、光谱、连续与飞秒激光性能,并实现了中心波长在1060 nm处脉宽为116 fs,平均输出功率为1.08 W,光光转换效率为33.1%的高效率飞秒激光输出,表明Yb^3+:Sr3Y2(BO3)4及其同体系晶体是一类优异的高效率飞秒激光材料。