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1. Department of Physics, Georgia Southern University, Statesboro GA,USA,30460
2. College of Engineering, Department of Physics and Astronomy, University of Georgia,GA Athens,USA,30602
[ "刘峰(1978-),男,吉林长春人,2007年于中科院长春光机所获凝聚态物理专业博士学位,2007年开始在美国佐治亚大学工作至今,现作为学术研究员任职于工学院。主要从事发光物理和发光材料的研究,尤其是对新颖荧光材料的谱学表征和光存储材料的物理功能调控,成果发表于Physical Review Letters和Nature Materials等学术刊物。E-mail:fliu@uga.edu" ]
[ "王笑军(1958-),男,吉林舒兰人,美国南佐治亚大学物理系教授,1992年于美国佐治亚大学获物理博士学位,1992-1995年在俄克拉荷马州立大学及加州大学尔湾分校做博士后研究,1995年在美国南佐治亚大学物理系工作至今。主要从事发光物理和发光材料的研究。发表学术论文及著作章节200余篇(章)。现为国际发光大会IPC委员,LSA、MRB杂志编辑,发光学报、中国稀土学报编委等。E-mail:xwang@georgiasouthern.edu" ]
纸质出版日期:2017-1-5,
收稿日期:2016-10-24,
修回日期:2016-11-27,
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刘峰, 王笑军,. 基质中非4f组态的电子态对Pr<sup>3+</sup>离子发光的影响[J]. 发光学报, 2017,38(1): 1-6
LIU Feng, WANG Xiao-jun,. Effects of Non-4f States on Pr<sup>3+</sup> Luminescence in Phosphors[J]. Chinese Journal of Luminescence, 2017,38(1): 1-6
刘峰, 王笑军,. 基质中非4f组态的电子态对Pr<sup>3+</sup>离子发光的影响[J]. 发光学报, 2017,38(1): 1-6 DOI: 10.3788/fgxb20173801.0001.
LIU Feng, WANG Xiao-jun,. Effects of Non-4f States on Pr<sup>3+</sup> Luminescence in Phosphors[J]. Chinese Journal of Luminescence, 2017,38(1): 1-6 DOI: 10.3788/fgxb20173801.0001.
三价镨离子(Pr
3+
)是一种备受关注的稀土发光离子。学者们在过去几十年里对其发光性质进行了大量的理论和实验研究。在不同的基质材料中,由于非4f组态的电子态与Pr
3+
离子发光能级相互作用,Pr
3+
离子可以展现从紫外到红外波段的不同特征的光发射。影响Pr
3+
离子发光的这些电子态可能源于4f5d激发组态、电荷迁移态或类激子态。本文中,我们以几种具有代表性的发光材料为例,简短地总结和评述了Pr
3+
离子发光的不同谱形;也尝试解释了几个新颖的实验现象,例如:杂质束缚激子态和电荷迁移态对发光的猝灭影响。我们希望这些相关概念和谱学结果的整理有助于读者更好地理解一些实验上的发光现象,并为设计发光材料提供新的思路。
Different emission wavelengths of Pr
3+
ion
from the ultraviolet to the infrared
may result from the effects of non-4f states in phosphors. Such non-4f states generally refer to the Pr
3+
4f5d state
exciton-like state or charge-transfer state. Here
we present a brief review on Pr
3+
luminescence by the means of emission spectral measurement in several representative phosphors. Several interesting spectral phenomena are reported and reviewed
including the effects of impurity-trapped exciton state and charge-transfer state on the luminescence quenching in the Pr
3+
-activated phosphors. We expect this review is beneficial to the readers to better understand their experimental findings
and to inspire them to design new and improved phosphor systems.
Pr3+1S0发射1D2发射杂质束缚激子态电荷迁移态红外发光
Pr3+1S0 emission1D2 emissionimpurity-trapped excitoncharge-transfer stateinfrared
SOMMERDIJIK J L, BRIL A, DE JAGER A W. Two photon luminescence with ultraviolet excitation of trivalent praseodymium[J]. J. Lumin., 1974, 8(4):341-343.
PIPER W W, DELUCA J A, HAM F S. Cascade fluorescent decay in Pr3+-doped fluorides:achievement of a quantum yield greater than unity for emission of visible light[J]. J. Lumin., 1974, 8(4):344-348.
SRIVASTAVA A M, BEER W W. Luminescence of Pr3+ in SrAl12O19:observation of two photon luminescence in oxide lattice[J]. J. Lumin., 1997, 71:285-290.
DIALLO P T, BOUTINAUD P, MAHIOU R, et al.. Red luminescence in Pr3+-doped calcium titanates[J]. Phys. Stat. Sol. ( a ), 1997, 160:255-263.
BOUTINAUD P, PINEL E, OUBAHA M, et al.. Making red emitting phosphors with Pr3+[J]. Opt. Mater., 2006, 28:9-13.
BOUTINAUD P, MAHIOU R, CAVALLI E, et al.. Red luminescence induced by intervalence charge transfer in Pr3+-doped compounds[J]. J. Lumin., 2007, 122-123:430-433.
YAMADA H, SUZUKI A, UCHIDA Y, et al.. A scintillator Gd2O2S:Pr,Ce,F for X-ray computed tomography[J]. J. Electrochem. Soc., 1989, 136(9):2713-2716.
SRIVASTAVA A M. Inter- and intraconfigurational optical transitions of the Pr3+ ion for application in lighting and scintillator technologies[J]. J. Lumin., 2009, 129:1419-1421.
SRIVASTAVA A M. Aspects of Pr3+ luminescence in solids[J]. J. Lumin., 2016, 169:445-449.
BLASE G, MEIJERINK A. The temperature dependence of the luminescence of Gd2O2S-Pr3+ upon 4f-5d excitation[J]. Inorg. Chm. Acta, 1989, 160:29-31.
DONEGA C M, MEIJERINK A, BLASE G. Non-radiative relaxation processes of the Pr3+ ion in solids[J]. J. Phys. Chem. Solids, 1995, 56(5):673-685.
CHEN H, LIAN R, YIN M, et al.. Luminescence concentration quenching of 1D2 state in YPO4:Pr3+[J]. J. Phys.: Condensed Matter, 2001, 13:1151-1158.
SRIVASTAVA A M, LECUNA C R, PEREZ D S, et al.. Pressure-induced Pr3+.3P0 luminescence in cubic Y2O3[J]. J. Lumin., 2014, 146:27-32.
PIPER W W, HAM F S, DELUCA J A. YF-Pr3+, a phosphor with a quantum efficiency greater than one for emission of visible light[J]. Bull. Am. Phys. Soc., 1974, 19:257-258.
WANG X J, HUANG S H, LU L, et al.. Energy transfer in Pr3+- and Er3+-codoped CaA112O19 crysta1[J]. Opt. Commun., 2001, 195:405-410.
HUANG S H, WANG X J, MELTZER R S, et al.. The mixing of the 4f2 1S0 state with the 4f5d states in Pr3+ doped SrAl12O19[J]. J. Lumin., 2001, 94-95:119-122.
LIU F, ZHANG J H, LU S Z, et al.. Explicit effects of 4f5d configuration on 4f2-4f2 electric dipole transitions in Pr3+-doped SrAl12O19[J]. Phys.Rev. B, 2006, 74:115112.
BLASE G, DONEGA C M, Luminescence of Pr3+ in indium borate (InBO3)[J]. Solid State Commun., 1994, 92(8):687-688.
DRIGGERS R G, VOLLMERHAUSEN R, DEVITT N, et al.. Impact of speckle on laser range-gated shortwave infrared imaging system target identification performance[J]. Opt. Eng., 2003, 42:738-746.
NACZYNSKI D J, TAN M C, ZEVON M, et al.. Rare-earth-doped biological composites as in vivo shortwave infrared reporters[J]. Nat. Commun., 2013, 4:2199.
IVANOVSKIKH K V, OGIEGLO J M, ZYCH A, et al.. Luminescence temperature quenching for Ce3+ and Pr3+ d-f emission in YAG and LuAG[J]. ECS J. Solid State Sci. Technol., 2013, 2(2):R3148-R3152.
HUANG S H, LU L, JIA W, et al.. The spectral properties of the 1S0 state in SrAl12O19:Pr[J]. Chem. Phys. Lett., 2001, 348:11-16.
VAN DER ENDE B M, AARTS L, MEIJERINK A. Near-infrared quantum cutting for photovoltaics[J]. Adv. Mater., 2009, 21:3073-3077.
VAN WIJNGAARDEN J T, SCHEIDELAAR S, VLUGT T J H, et al.. Energy transfer mechanism for downconversion in the (Pr3+, Yb3+) couple[J]. Phys. Rev. B, 2010, 81:155112.
GUILLE A, PEREIRA A, MOINE B, et al.. NaLaF4:Pr3+,Yb3+, an efficient blue to near infra-red quantum cutter[J]. APL Mater., 2013, 1:062106.
SERRANO D, BRAUD A, DOUALAN J L, et al.. Two-step quantum cutting efficiency in Pr3+-Yb3+ codoped KY3F10[J]. Phys. Rev. B, 2013, 88:205144.
GRZESZKIEWICZ K, MARCINIAK L, STREK W, et al.. Downconversion in Y2Si2O7:Pr3+,Yb3+ polymorphs for its possible application as luminescent concentrators in photovoltaic solar-cells[J]. J. Lumin., 2016, 177:172-177.
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