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)。

SrBPO5∶Ho3+荧光粉的制备、性能及第一性原理计算

运用高温固相法合成SrBPO5∶Ho^3+,用X射线衍射仪(XRD)、能谱仪(EDS)以及荧光光度计(PL)对合成产物的结构、组成和发光性质进行了研究。结果表明:少量掺杂Ho不会影响基质的晶体结构,Ho均匀分布在基质材料中;荧光材料呈现出Ho^3+的特征发射,发光区域在绿色区域,当掺杂量为0.03 mol时发射强度最大;掺杂后计算得到SrBPO5∶Ho^3+的VBM和CBM之间的带隙值为5.53 eV,相对掺杂前略微减少,且SrBPO5∶Ho^3+体系属于直接带隙结构,有利于发光;Ho的掺杂在费米能级附近引起杂质能级。

SrBPO5:Dy^3+荧光粉的制备及光谱性能研究

通过高温固相法制备了用于紫外激发的系列SrBPO_5:Dy^(3+)荧光粉,并对样品进行了XRD分析和发光性能测试。结果表明,合成样品为单一相的SrBPO_5材料;在388 nm紫外光激发下,样品的发射光谱包括485和575 nm两个发射峰。研究了Dy^(3+)浓度,Mg^(2+)加入量,烧结温度以及电荷补偿剂对发射光谱的影响。当Dy^(3+)掺杂摩尔浓度为4 mol%时发光强度最强;随着Mg^(2+)的加入量的增加B/Y峰的强度比不断增加;最佳烧结温度为1 100℃;Na^+作为电荷补偿剂效果最佳。该荧光粉有较强的黄色发射峰,可以增强UV激发的白光LED的黄光成分从而提高其穿透雾霾的能力。

共掺碱金属对白光LEDs用SrBPO_5:Sm^(3+)荧光粉发光的增强作用（英文）

利用传统的高温固相法合成了一种橘红色Sr BPO_5:Sm^(3+)荧光粉。通过X射线衍射(XRD)确定荧光粉的组成,研究了样品的光致激发(PLE)和光致发射(PL)光谱,探究Sm^(3+)离子浓度对样品发光性能的影响及浓度猝灭机理,通过测试不同温度下的发射光谱分析了样品的热稳定性,研究反应温度和电荷补偿剂对发光性能的影响。最后讨论了Sr BPO_5:Sm^(3+),R+荧光粉的色坐标。结果表明:Sr BPO_5:Sm^(3+),Li^+是一种潜在的用于UV激发的白光LED的橘红色荧光粉。

The effects of Er^(3+) ion concentration on 2.0-μm emission performance in Ho^(3+)/Tm^(3+) co-doped Na_(5)Y_(9)F_(32) single crystal under 800-nm excitation

Na_(5)Y_(9)F_(32) single crystals doped with ~0.8-mol% Ho^(3+),~1-mol% Tm^(3+),and various Er^(3+) ion concentrations were prepared by a modified Bridgman method.The effects of Er^(3+)ion concentration on 2.0-μm emission excited by an800-nm laser diode were investigated with the help of their spectroscopic properties.The intensity of 2.0-μm emission reached to maximum when the Er^(3+) ion concentration was ~1 mol%.The energy transfer mechanisms between Er^(3+),Ho^(3+),and Tm^(3+) ions were identified from the change of the absorption spectra,the emission spectra,and the measured decay curves.The maximum 2.0-μm emission cross section of the Er^(3+)/Ho^(3+)/Tm^(3+)tri-doped Na_(5)Y_(9)F_(32) single crystal reached 5.26 × 10^(-21) cm^(2).The gain cross section spectra were calculated according to the absorption and emission cross section spectra.The cross section for ~2.0-μm emission became a positive gain once the inversion level of population was reached 30%.The energy transfer efficiency was further increased by 11.81% through the incorporation of Er^(3+) ion into Ho^(3+)/Tm^(3+) system estimated from the measured lifetimes of Ho^(3+)/Tm^(3+)-and Er^(3+)/Ho^(3+)/Tm^(3+)-doped Na_(5)Y_(9)F_(32)single crystals.The present results illustrated that the Er^(3+)/Ho^(3+)/Tm^(3+)tri-doped Na_(5)Y_(9)F_(32) single crystals can be used as promising candidate for 2.0-μm laser.