SrZn2(PO4)2:Sn2+,Mn2+荧光粉的发光性质及其能量传递机理

采用高温固相法制备了SrZn₂(PO₄)₂:Sn²⁺(SZ₂P:Sn²⁺), SrZn₂(PO₄)₂:Mn²⁺(SZ₂P:Mn²⁺), SrZn₂ (PO₄)₂:Sn²⁺, Mn²⁺(SZ₂P:Sn²⁺, Mn²⁺) 荧光粉. 通过X射线衍射、激发和发射光谱详细研究了荧光粉的物相和发光性质. 在SrZn₂(PO₄)₂ 基质中, Sn²⁺离子发射光谱是峰值位于461 nm宽带谱, 归属于Sn²⁺离子的³P₁→¹S₀能级跃迁, SZ₂P:Mn²⁺激发光谱由基质吸收带(200–300 nm)和位于352, 373, 419, 431和466 nm的一系列激发峰组成, 分别对应Mn²⁺离子的⁶A₁(⁶S)→⁴E(⁴D), ⁶A₁(⁶S)→⁴T₂(⁴D), ⁶A₁(⁶S)→[⁴A₁(⁴G), ⁴E(⁴G)], ⁶A₁(⁶S)→⁴T₂(⁴G)和⁶A₁(⁶S)→⁴T₁(⁴G)能级跃迁, 因此, SZ₂P:Sn²⁺ 的发射光谱与SZ₂P:Mn²⁺的激发光谱有较大范围的重叠. 结果表明Sn²⁺对Mn²⁺发光有明显的敏化作用. 基于Dexter电多极相互作用能量传递公式和Reisfeld近似原理分析, 荧光粉SZ₂P:Sn²⁺, Mn²⁺中Sn²⁺-Mn²⁺离子之间的能量传递机理属于电四极-电四极相互作用引起的共振能量传递, 并计算出Sn²⁺-Mn²⁺离子之间能量传递临界距离R_c ≈ 1.78 nm. 通过改变Sn²⁺, Mn²⁺离子掺杂浓度, 实现了荧光粉发光颜色的调节, 在254 nm短波紫外激发下荧光粉发出较强的蓝白光. 研究结果表明SZ₂P:Sn²⁺, Mn²⁺荧光粉有望应用于紧凑型节能灯照明领域, 随着半导体紫外芯片技术的发展, 有潜力应用于未来的白光发光二极管照明领域.     

Ce3+, Mn2+共掺的Ca4Y6 (SiO4)6F2的发光性质和能量传递

采用高温固相法制备了Ca_4-xY_5.95 (SiO₄)₆F₂:0.05Ce³⁺, _xMn^{2 +}系列荧光粉,并对其发光性质以及Ce³⁺, Mn^{2 +}在Ca₄Y₆ (SiO₄)₆F₂ (CYSF)基质中的能量传递过程进行了研究.相结构研究表明: CYSF属于一种基于磷灰石结构的类质同象化合物.CYSF: 0.05Ce³⁺, _xMn²⁺荧光粉在200–373 nm为宽带激发光谱,Ce³⁺和Mn²⁺在408 nm和602 nm的发射峰分别由Ce³⁺的5d→4f的跃迁和Mn²⁺的⁴T₁ (⁴G)→ ⁶A₁ (⁶S)的跃迁产生.光谱重叠现象以及荧光寿命测试结果证明了Ce³⁺对Mn²⁺具有敏化作用,能级结构分析进一步证实该体系中存在Ce³⁺→Mn²⁺的能量传递过程,可有效地将Ce³⁺的蓝光转换为红橙光. 关键词： 磷灰石 发光性质 能量传递     

Na4Ca3(AlO2)10∶Eu2+,Mn2+荧光粉的发光特性

采用高温固相法,制得一种新型荧光粉Na₄Ca₃(AlO₂)₁₀∶Eu²⁺,Mn²⁺。样品的结构和发光性质分别由X射线衍射谱和荧光光谱来表征。在Na₄Ca₃(AlO₂)₁₀∶Eu²⁺的激发光谱中出现了Eu²⁺的f-d跃迁吸收带;在发射光谱中,出现蓝光发射,峰值位于441 nm。当在Na₄Ca₃(AlO₂)₁₀∶Eu²⁺中掺杂Mn²⁺时,发生了Eu²⁺→Mn²⁺的能量传递,在542 nm处出现了Mn²⁺的发射峰。在Na₄Ca₃(AlO₂)₁₀∶Eu²⁺,Mn²⁺中,随着Mn²⁺浓度的增加,Eu²⁺粒子的发射强度减弱,而Mn²⁺粒子的发射强度增强,且Eu²⁺离子发射的衰减时间缩短,同时色度由蓝光移向白光。     

Ba9Y2(SiO4)6: Ce3+,Mn2+荧光粉的发光特性及能量传递

利用高温固相法制备了Ba₉Y₂(SiO₄)₆:Ce³⁺,Mn²⁺(BYS:Ce³⁺,Mn²⁺)荧光粉,并通过X射线衍射(XRD)谱、激发和发射光谱及荧光寿命的测试对材料的结构、发光特性和能量传递进行了研究。在327 nm激发下,BYS:Ce³⁺,Mn²⁺发射光谱中包含2个发射峰,分别为位于407 nm的Ce³⁺的蓝紫光发射和位于597 nm的Mn²⁺的红光发射。在该体系中,发现了Ce³⁺向Mn²⁺的有效能量传递,使得Mn²⁺在597 nm处的红光发射显著提高,当x(Mn²⁺)=0.25时,BYS:Ce³⁺,xMn²⁺的能量传递效率可达39%。实验表明,该荧光粉可为紫外基白光LED提供良好的红光光源。     

真空紫外光激发下Ce3+、Tb3+激活的BaCa2(BO3)2的发光性质

利用XRD、VUV及UV光谱等方法对Ce³⁺、Tb³⁺离子掺杂以及Ce³⁺、Tb³⁺离子共掺的3种BaCa₂(BO₃)₂荧光粉的相纯度、发光性质、浓度猝灭现象进行研究。结果表明:3种荧光粉在VUV波段有较好的吸收,基质吸收带位于140～190 nm范围。Ce³⁺在BaCa₂(BO₃)₂的最低4f5d跃迁带位置在360 nm附近,其5d→²F_J(J=5/2, 7/2)发射峰分别位于393,424 nm。Tb³⁺掺杂的样品在172 nm激发下的发射光谱由4个窄带组成,分别对应⁵D₄→⁷F_J(J=3,4,5,6)的跃迁,其中占主导位置的是⁵D₄→⁷F₅的跃迁,大约位于543 nm处,主要为绿光发射。在Ce³⁺,Tb³⁺离子共掺杂的BaCa₂(BO₃)₂光谱中,观察到Ce³⁺-Tb³⁺离子间有能量传递。     

Eu2+,Mn2+在BaZnP2O7中的发光及Eu2+→Mn2+能量传递

采用高温固相法合成了BaZnP₂O₇:Eu²⁺,Mn²⁺荧光粉,并对其发光性质及Eu²⁺对Mn²⁺的能量传递机理进行了研究.Eu²⁺和Mn²⁺在380 nm和670nm的发射峰分别由Eu²⁺的5d—4f跃迁和Mn²⁺的⁴T₁(^{4关键词： 磷酸盐 2+}')" href="#">Eu²⁺ 2+')" href="#">Mn²⁺ 能量传递     

Ba2SiO4:Ce3+,Mn2+荧光粉的制备与光谱性质

用高温固相反应法合成了Ba₂SiO₄:xCe³⁺,yMn²⁺(x=0~0.2, y=0~0.15)荧光粉,研究了荧光粉的晶体结构和发光性质。在紫外光激发下,Ba₂SiO₄:xCe³⁺的发射光谱为位于384 nm附近的宽带。Ba₂SiO₄:Mn²⁺样品的发射光谱位于376 nm的宽带较强,红光发射极弱。在Ce³⁺和Mn²⁺共掺的Ba₂SiO₄:xCe³⁺,yMn²⁺样品中,位于606 nm附近的红光发射较强,来源于Mn²⁺的⁴T₁(⁴G)-⁶A₁(⁶S)跃迁。这说明Ce³⁺离子将部分能量传递给了Mn²⁺离子,有效地敏化了Mn²⁺离子的发光。当Ce³⁺的摩尔分数为0.2、Mn²⁺的摩尔分数为0.075时,Ba₂SiO₄:xCe³⁺,yMn²⁺荧光粉位于606 nm的Mn²⁺的发射峰最强。     

红色长余辉材料Zn3(PO4)2：Mn2+,Ga3+的合成及光谱性质

采用高温固相法合成α、β和γ-Zn₃(PO₃)₂:Mn²⁺,Ga³⁺(ZPMG),XRD分析表明,高温合成过程中淬火条件有利于β相的形成,退火条件有利于γ相的形成。三种磷光粉的激发光谱分别位于246nm(α)、234nm(β和γ)的宽带谱。α相的发射光谱为位于508nm的锐线谱,β和γ相的发射光谱均存在两个谱带,分别位于508nm的绿色光谱区和616nm的红色光谱区。两种发射均归属为Mn²⁺的⁴T₁(⁴G)→⁶A_1g(⁶S)跃迁,但是由于Mn²⁺在Zn₃(PO₃)₂结构中的配位数不同,故发光颜色及强度均不同。对于余辉发射,只能观察到红色余辉光谱。     

NaZnLa(PO4)2中Ce3+和Tb3+的发光

采用高温固相反应合成了NaZnLa(PO₄)₂中掺杂Ce³⁺、Tb³⁺的荧光体,对其晶体结构、发光行为进行了研究,并尝试对NaZnLa(PO₄)₂:Ce,Tb荧光体进行调制。NaZnLa(PO₄)₂是LaPO₄的同构物,为单斜晶系独居石结构,从XRD谱数据得到NaZnLa(PO₄)₂基质的晶胞参数为a=0.6823nm,b=0.7045nm,c=0.6497nm,β=1039°,v=0.303nm³,其晶胞参数与单斜LaPO₄的晶胞参数相似。在NaZnLa(PO₄)₂:Ce,Tb荧光体中,Ce³⁺对Tb³⁺有良好的敏化作用,掺杂适量的BO₃^3-、Al³⁺、Dy³⁺,可以增强发光亮度。     

红色长余辉材料Mg2SiO4：Dy3+,Mn2+的制备及发光特性

用高温固相法制备了长余辉发光材料Mg₂SiO₄:Dy³⁺,Mn²⁺,对这种材料的红色长余辉性质进行了研究.对以不同掺杂浓度单掺杂Mn²⁺、单掺杂Dy³⁺以及双掺杂Dy³⁺,Mn²⁺的Mg₂SiO₄体系,通过在紫外激发下的发射光谱及其激发光谱的研究,确认了在双掺杂体系中,峰值为660nm的发光带对应着Mn²⁺的⁴T₁(⁴G)→⁶A₁(⁶S)跃迁,Mn²⁺为主要发光中心.Mn²⁺的660nm发射的激发谱分布很宽,样品在近紫外和可见光区都有良好的吸收,长波边可达600nm,是这种材料的一个显著优点.还研究了双掺杂体系中Dy³⁺对Mn²⁺的660nm发光带的敏化作用.另外,通过对单掺杂、双掺杂体系热释光曲线的比较,揭示了双掺杂体系中Dy³⁺的陷阱作用.     

Photoluminescence properties of Ca9Lu(PO4)7:Ce3+, Mn2+ prepared by conventional solid-state reaction

A new red-emitting phosphor Ca₉Lu(PO₄)₇:Ce³⁺, Mn²⁺ has been synthesized by solid-state reaction, and its luminescence properties have been investigated. The broad red emission peaked at 645 nm of Mn²⁺ is greatly enhanced by the sensitizer Ce³⁺ due to efficient energy transfer from Ce³⁺ to Mn²⁺. The energy transfer was demonstrated to belong to a resonant type via a dipole–quadrupole mechanism. The critical distance for Ce³⁺→Mn²⁺ energy transfer was calculated to be 15.04 Å by concentration quenching method. Preliminary results indicate that the phosphor might be a promising red phosphor for UV-based white LEDs.     

Photoluminescence and efficient energy transfer from Ce3+ to Tb3+ or Mn2+ in Ca9ZnLi(PO4)7 host

Structural and spectroscopic characterizations of the Ce³⁺/Tb³⁺(Mn²⁺) solely and Ce³⁺–Tb³⁺(Mn²⁺) doubly doped phosphate compound Ca₉ZnLi(PO₄)₇ with β-Ca₃(PO₄)₂ structure have been performed by powder X-ray diffraction and photoluminescence spectra measurements. The weak green emission from Tb³⁺ and red emission from Mn²⁺ are significantly enhanced by introduction of sensitizer Ce³⁺ ions due to an efficient resonant-type energy transfer from Ce³⁺ to activators Tb³⁺ or Mn²⁺. The energy transfer efficiency and the mechanism have been estimated based on spectroscopic data. Meanwhile, the critical distances for energy transfer between the Ce³⁺ and Tb³⁺ or Mn²⁺ ions are also calculated by the method of spectral overlapping.     

Luminescence properties and energy transfer in Eu2+, Mn2+ codoped Na(Sr,Ba)PO4 phosphor

Eu²⁺ and Mn²⁺ singly doped and codoped Na(Sr,Ba)PO₄ phosphors were synthesized, and their luminescent properties were investigated. A broad blue emission and a broad orange emission band were observed in Na(Sr,Ba)PO₄:Eu²⁺, Mn²⁺ phosphor. The resonant-type energy transfer from Eu²⁺ to Mn²⁺ was demonstrated, and the energy transfer efficiency was also calculated according to their emission spectra. Based on the principle of energy transfer, the emission intensity ration of Eu²⁺ and Mn²⁺ could be appropriately tuned by adjusting the contents of activators. Due to the strong absorption in the 250–400 nm range, Na(Sr,Ba)PO₄:Eu²⁺, Mn²⁺ phosphor could be used as a potential candidate for near-UV white light-emitting diodes (LEDs).     

Luminescence spectroscopy and energy transfer in Eu2+/Mn2+-doped KCaPO4 phosphors

Eu²⁺/Mn²⁺-doped KCaPO₄ phosphors were prepared by conventional solid-state reaction. X-ray powder diffraction (XRD), SEM, photoluminescence excitation, and emission spectra, and the luminescence decay curves were measured. Mn²⁺ singly doped KCaPO₄ shows the weak origin-red luminescence band peaked at about 590 nm. The Eu²⁺/Mn²⁺ co-doped phosphors emit two distinctive luminescence bands: a blue one centered at 480 nm originating from Eu²⁺ ions and a broad red-emitting one peaked at 590 nm from Mn²⁺ ions. The luminescence intensity from Mn²⁺ ions can be greatly enhanced with the co-doping of Eu²⁺ ions. The efficient energy transfer from Eu²⁺ to Mn²⁺ was verified by the photoluminescence spectra together with the luminescence decay curves. The resonance-type energy transfer via a dipole–quadrupole interaction mechanism was supported by the decay lifetimes. The emission colors could be tuned by changing the Mn²⁺-doping concentration.     

Er3+/Yb3+掺杂氟硅铅酸盐微晶玻璃的上转换发光

制备了微晶体尺寸大约在10—12 nm范围内的Er³⁺,Yb³⁺共掺杂透明氟硅铅酸盐微晶玻璃.相同功率激发下,纳米微晶玻璃中Er³⁺离子的²H_11/2,⁴S_3/2→⁴I_15/2的绿色上转换荧光和⁴F_9/2→关键词： 3+')" href="#">Er³⁺ 3+')" href="#">Yb³⁺ 能量传递 纳米微晶玻璃     

Crystal growth,luminescence and scintillation properties of Eu2+:CeBr3 crystals

Eu²⁺:CeBr₃ crystals were grown by vertical Bridgman growth method and slight aliovalent doping of Eu²⁺ in the CeBr₃ crystal did not change the crystal structure. The X-ray stimulated luminescence, photoluminescence, decay kinetics and scintillation properties were investigated at room temperature. The X-ray stimulated luminescence spectra exhibited wide broad emission bands from 3.54 eV to 2.95 eV in the Eu²⁺:CeBr₃ crystal with high content of 620 ppm of Eu²⁺, which were the overlap of the emission bands ascribed to 5d → 4f transition of Ce³⁺ and 4f⁶5 d¹ → 4f⁷ transition of Eu²⁺, respectively. When the content of Eu²⁺ was decreased to 70 ppm, another emission band centered at 2.29 eV was observed. The photoluminescence spectra showed the energy transfer from Ce³⁺ to Eu²⁺. This decreased the Ce³⁺ emission intensity but enhanced the Eu²⁺ emission intensity. The photoluminescence decay time of Ce³⁺ emission decreased from 14 ns to 10 ns when the content of Eu²⁺ increased from 70 ppm to 620 ppm. The decay time of the emission of 525 nm did not change with the excitation wavelength and Eu²⁺ content, which could be assigned to the excitons that were bound on Eu²⁺ related centers. The light output of the Eu:CeBr₃ crystal under the excitation of ²⁴¹Am radioactive source was less than 20.2% of Tl:NaI crystal.     

The luminescence properties of Eu2+ doped Na2CaMg(PO4)2 phosphor

The blue-emitting phosphors of Eu²⁺-doped Na₂CaMg(PO₄)₂ were prepared by high-temperature solid-state reaction. The crystal phase formation was confirmed by X-ray powder diffraction measurement. The luminescence properties were investigated by photoluminescence excitation and emission spectra. The phosphor exhibited the blue luminescence due to the 4f⁶5d¹→4f⁷ transition of Eu²⁺ ions under the excitation of near UV light. The influence of temperature on the luminescence intensities and decay lifetimes of Eu²⁺ was investigated. An unusual increase of the decay lifetimes of the 4f⁶5d emission of Eu²⁺ ion is observed in Na₂CaMg(PO₄)₂ from 10 K to room temperature. The thermal stability of the luminescence of Eu²⁺-doped Na₂CaMg(PO₄)₂ was discussed.     

A novel scheme to acquire enhanced up-conversion emissions of Ho3+ and Yb3+ co-doped Sc2O3

A detailed investigation about the effect of Sc₂O₃: 1 mol%Ho³⁺/5 mol%Yb³⁺ co-doped with Ce⁴⁺ ions prepared by sol-gel methods was performed systematically. Under the excitation of 980 nm laser diode, both green emission (553 nm, ⁵F₄/⁵S₂→⁵I₈) and red emission (672 nm, ⁵F₅→⁵I₈) were both observed in the emission spectra of the samples, which were found to be two-photon process and sensitized by Yb³⁺ ions. With the increasing of Ce⁴⁺ ions, the up-conversion green emission intensity are increased by 6.52, 8.69, 10.85, 13.92 and 16.66 fold, corresponding to the Ce⁴⁺ ions concentrations from 5 mol% to 13 mol%, respectively. The number of photons are necessary to populate the upper emitting state decreases to 2 and the infrared absorption coefficient is reduced, when the Ce⁴⁺ ions concentration increase to 13 mol%. Ce⁴⁺ ions play an important role in tailoring the local crystal field around Ho³⁺ ions, lowering the highest phonon cut-off energy of matrix and reducing the infrared absorption coefficient, thus hindering the non-radiative processes, which contribute to the increased emission intensity. The excellent enhancement makes it a promising multifunctional optical luminescence material.     

Luminescence enhancement in (Nd+Ce) doped SiO2 : Al2O3 sol–gel glasses

An enhancement in NIR luminescence from Nd³⁺-doped Ce³⁺ co-doped SiO₂+Al₂O₃ sol–gel glasses has been observed. The lasing transition (⁴F_3/2→⁴I_11/2) at 1072 nm from the dual rare-earth Nd³⁺+Ce³⁺-doped glasses has shown an emission strength of about five times that of the single rare-earth ion Nd³⁺-doped glass. From the measurement of lifetimes of the transition at 1072 nm, the transfer rate (W_tr), critical distance (R₀) and energy transfer efficiency (η) of the neodymium glasses have been calculated.