参考文献
[1] 刘如熹.白光发光二极管制作技术——由芯片至封装[M].北京:化学工业出版社,2015.
[2] 冯志庆,白兰,曹保胜,等.基于Er-Yb共掺杂硼硅酸盐玻璃的光学温度传感[J].中国科学,2010,40(8):955-958.
[3] J.Brübach,C.Pflitsch,A.Dreizler,et al.On Surface Temperature Measurements with Thermographic Phosphors:A Review[J].Progress in Energy and Combustion Science,2013,39(1):37-60.
[4] D.Q.Chen,M.Xu,P.Huang.Core@shell Up-converting Nanoarchitectures for Luminescent Sensing of Temperature[J].Sensors and Actuators B:Chemical,2016,231:576-583.
[5] 张希艳,卢利平,柏朝晖,等.稀土发光材料[M].北京:国防工业出版社,2005.
[6] 黄世华,由芳田,彭洪尚,等.表面对纳米微粒中稀土离子光谱性质的影响[J].中国稀土学报,2007,25(4):396-401.
[7] 张思远.稀土离子的光谱学:光谱性质和光谱理论[M].北京:科学出版社,2008.
[8] G.H.Dieke.Spectra and Energy Levels of Rare-Earth Ions in Crystals[M].New York:Interscience Publishers,1968.
[9] 洪广言.稀土发光材料——基础与应用[M].北京:科学出版社,2011.
[10]许少鸿.固体发光[M].北京:清华大学出版社,2011.
[11] D.L.Dexter.A Theory of Sensitized Luminescence in Solids[J].The Journal of Chemical Physics,2004,21(5):836-850.
[12] K.B.Eisenthal,S.Siegel.Influence of Resonance Transfer on Luminescence Decay[J].The Journal of Chemical Physics,1964,41(3):652-655.
[13] C.R.Ronda.Luminescence:from Theory to Applications[M].Hoboken:John Wiley and Sons,2007.
[14] Z.Y.Ren,C.Y.Tao,H.Yang,et al.A Novel Green Emitting Phosphor SrAl2B2O7:Tb3+[J].Materials Letters,2007,61(8):1654-1657.
[15]郭浩中,赖芳仪,郭守义.LED原理与应用[M].北京:化学工业出版社,2013.
[16]诸玉华,潘有彬,沈吉梅.LED照明光色对健康的影响[J].中国照明电器,2015,(1):5-8.
[17]田民波,朱焰焰.白光LED照明技术[M].北京:科学出版社,2012.
[18] G.Blasse,B.C.Grabmaier.Luminescent Materials[M].Berlin:Spring-Verlag,1994.
[19]王晓明,郭伟玲,高国,等.LED——新一代照明光源[J].现代显示,2005,(7):15-19.
[20]徐叙溶,苏勉曾.发光学与发光材料[M].北京:化学工业出版社,2004.
[21]陈晓波,张光寅,李美仙,等.三维立体显示——频率上转换研究的新进展[J].光谱学与光谱分析,1998,18(3):257-260.
[22]杨清德,杨兰云.LED及其应用技术问答[M].北京:电子工业出版社,2011.
[23]沈雷军,乔君.新型白光LED用块体发光材料研究进展[J].稀土信息,2015,(12):12-14.
[24]余阳,刘自军,陈乔乔,等.Dy3+掺杂硼硅酸盐玻璃的发光特性[J].物理学报,2013,(1):455-459.
[25] F.E.Auzel.Materials and Devices using Double-pumped Phosphors with Energy Transfer[J].Proceedings of the IEEE,1973,61(6):758-786.
[26] L.F.Johnson,G.J.Guggenheim.Infrared-Pumped Visible Laser[J].Applied Physics Letters,1971,19(2):44-47.
[27] F.Tong,W.P.Risk,R.M.Macfarlane,et al.551nm Diode Laser Pumped Up-conversion Laser[J].Electronics Letters,1989,25(20):1389-1391.
[28] J.Y.Allain,M.Monerie,H.Poignant.Blue Up-conversion Fluorozirconate Fiber Laser[J].Electronics Letters,1990,26(3):166-168.
[29] H.A.Höppe.Recent Developments in the Field of Inorganic Phosphors[J].Angewandte Chemie International Edition,2010,48(20):3572-3582.
[30] J.F.Suyver,A.Aebischer,D.Biner,et al.Novel Materials Doped with Trivalent Lanthanides and Transition Metal Ions Showing Near-infrared to Visible Photon Up-conversion[J].Optical Materials,2005,27(6):1111-1130.
[31] B.S.Richards.Luminescent Layers for Enhanced Silicon Solar Cell Performance:Down-conversion[J].Solar Energy Materials and Solar Cells,2006,90(9):1189-1207.
[32] C.Sanchez,B.Lebeau.Optical Properties of Functional Hybrid Organic-Inorganic Nanocomposites [J].Advanced Materials,2003,15(23):1969-1994.
[33]杜丕一,宋晨路,樊先平,等.先进材料进展[M].杭州:浙江大学出版社,2011.
[34] F.Auzel.Up-conversion and Anti-stokes Processes with f and d ions in Solids[J].Chemical Reviews,2004,104(1):139-173.
[35] P.R.N.Childs,J.Greenwood,C.A.Long.Review of Temperature Measurement[J].Review of Scientific Instruments,2000,71(8):2959-2978.
[36] X.F.Wang,Q.Liu,Y.Y.Bu,et al.Optical Temperature Sensing of Rare-Earth Ion Doped Phosphors[J].RSC Advances,2015,5(105):86219-86236.
[37] S.A.Wade,S.F.Collins,G.W.Baxter.Fluorescence Intensity Ratio Technique for Optical Fiber Point Temperature Sensing[J].Journal of Applied Physics,2003,94(8):4743-4756.
[38] A.H.Khalid,K.Kontis.Thermographic Phosphors for High Temperature Measurements:Principles,Current State of the Art and Recent Applications[J].Sensors,2008,8(9):5673-5744.
[39] B.Dong,B.S.Cao,Y.Y.He,et al.Temperature Sensing and In Vivo Imaging by Molybdenum Sensitized Visible Up-conversion Luminescence of Rare-Earth Oxides[J].Advanced Materials,2012,24(15):1987-1993.
[40] F.Wang,Y.Han,C.S.Lim,et al.Simultaneous Phase and Size Control of Up-conversion Nanocrystals through Lanthanide Doping[J].Nature,2010,463(7248):1061-1065.
[41] S.S.Zhou,S.Jiang,X.T.Wei,et al.Optical Thermometry Based on Up-conversion Luminescence in Yb3+/Ho3+Co-doped NaLuF4[J].Journal of Alloys and Compounds,2014,588:654-657.
[42] A.Pandey,V.K.Rai,V.Kumar,et al.Up-conversion Based Temperature Sensing Ability of Er3+-Yb3+Co-doped SrWO4:an Optical Heating Phosphor[J].Sensors and Actuators B:Chemical,2015,209:352-358.
[43] H.Suo,C.F.Guo,Z.Yang,et al.Thermometric and Optical Heating Bi-functional Properties of Up-conversion Phosphor Ba5Gd8Zn4O21:Er3+/Yb3+[J].Journal of Materials Chemistry C,2015,3(28):7379-7385.
[44] G.Y.Chen,H.Agren,T.Y.Ohulchanskyy,et al.Light Up-converting Core-shell Nanostructures:Nanophotonic Control for Emerging Applications[J].Chemical Society Reviews,2015,44(6):1680-1713.
[45] S.Q.Zhou,C.R.Li,Z.F.Liu,et al.Thermal Effect on Up-conversion in Er3+/Yb3+Co-doped Silicate Glass[J].Optical Materials,2007,30(4):513-516.
[46] S.S.Zhou,K.M.Deng,X.T.Wei,et al.Up-conversion Luminescence of NaYF4:Yb3+,Er3+for Temperature Sensing[J].Optics Communications,2013,291:138-142.
[47] Y.M.Yang,C.Mi,F.Yu,et al.Optical Thermometry Based on the Up-conversion Fluorescence from Yb3+/Er3+Co-doped La2O2S Phosphor[J].Ceramics International,2014,40(7):9875-9880.
[48] K.Z.Zheng,Z.Y.Liu,C.J.Lv,et al.Temperature Sensor Based on the UV Up-conversion Luminescence of Gd3+in Yb3+-Tm3+-Gd3+Co-doped NaLuF4 Microcrystals[J].Journal of Materials Chemistry C,2013,1(35):5502-5507.
[49] M.K.Mahata,K.Kumar,V.K.Rai.Er3+-Yb3+Doped Vanadate Nanocrystals:A Highly Sensitive Thermographic Phosphor and its Optical Nanoheater Behavior[J].Sensors and Actuators,B:Chemical,2015,209:775-780.
[50] K.Elzbieciak,A.Bednarkiewica,L.Marciniak.Temperature Sensitivity Modulation Through Crystal Filed Engineering in Ga3+Co-doped Gd3Al5-xGaxO12:Cr3+,Nd3+Nanothermometers[J].Sensors and Actuators,B:Chemical,2018,269:96-102.
[51] L.Marciniak,A.Bednarkiewicz.Nanocrystalline NIR-to-NIR Luminescent Thermometer Based on Cr3+,Yb3+Emission[J].Sensors and Actuators,B:Chemical,2017,243:388-393.
[52] B.R.Reddi,I.Kamma,P.Kommidi.Optical Sensing Techniques for Temperature Measurement[J].Applied Optics,2013,52(4):33-39.
[53]林杨杨,陈铠炀,唐霞艳,等.Er3+/Yb3+共掺杂氧氟硼硅酸盐微晶玻璃绿色上转换发光的温度特性[J].发光学报,2015,36(9):1001-1005.
[54] L.Q.Yao,G.H.Chen,T.Yang,et al.Energy Transfer,Tunable Emission and Optical Thermometry in Tb3+/Eu3+Co-doped Transparent NaCaPO4 Glass Ceramics[J].Ceramics International,2016,42(11):13086-13090.
[55] Y.Chen,X.Y.Liu,G.H.Chen,et al.Up-conversion Luminescence and Temperature Sensing Characteristics of Er3+/Yb3+Co-doped Phosphate Glasses[J].Journal of Materials Science:Materials in Electronics,2017,28(20):15657-15662.
[56] H.Berthou,C.K.Jörgensen.Optical-Fiber Temperature Sensor Based on Up-conversion-Excited Fluorescence[J].Optics Letters,1990,15(19):1100-1102.
[57] G.S.Maciel,L.D.Menezes,A.S.L.Gomes,et al.Temperature Sensor Based on Frequency Up-conversion in Er3+Doped Fluoroindate Glass[J].Photonics Technology Letters,1996,7(12):1474-1476.
[58] P.V.D.Santos,M.Araújo,A.S.Gouveia-Neto,et al.Optical Temperature Sensing Using Up-conversion Fluorescence Emission in Er3+,Yb3+Co-doped Chalcogenide Glass[J].Applied Physics Letters,1998,73(5):578-580.
[59] F.Vetrone,R.Naccache,A.Zamarrón,et al.Temperature Sensing Using Fluorescent Nanothermometers[J].ACS Nano,2010,4(6):3254-3258.
[60] S.F.León Luis,U.R.Rodríguez Mendoza,P.HaroGonzále,et al.Role of the Host Matrix on the Thermal Sensitivity of Er3+Luminescence in Optical Temperature Sensors[J].Sensors and Actuators,B:Chemical,2012,174:176-186.
[61] A.K.Singh,S.K.Singh,B.K.Gupta,et al.Probing a Highly Efficient Dual Mode:Down-upconversion Luminescence and Temperature Sensing Performance of Rare-Earth Oxide Phosphors[J].Dalton Transactions,2013,42(4):1065-1072.
[62] P.Du,L.H.Luo,W.P.Li,et al.Optical Temperature Sensor Based on Up-conversion Emission in Er-doped Ferroelectric 0.5Ba(Zr0.2Ti0.8)O3-0.5(Ba0.7Ca0.3)TiO3 Ceramic[J].Applied Physics Letters,2014,104(15):152902-152906.
[63] D.Q.Chen,Z.Y.Wan,Y.Zhou,et al.Dual-Phase Glass Ceramic:Structure,Dual-Modal Luminescence,and Temperature Sensing Behaviors[J].ACS Applied Materials&Interfaces,2015,7(34):19484-19493.
[64] F.F.Hu,J.K.Cao,X.T.Wei,et al.Luminescence Properties of Er3+-doped Transparent NaYb2F7 Glass-ceramics for Optical Thermometry and Spectral Conversion[J].Journal of Materials Chemistry C,2016,4(42):9976-9985.
[65] L.Mukhopadhyay,V.K.Rai,R.Bokolia,et al.980nm Excited Er3+/Yb3+/Li+/Ba2+:NaZnPO4 Up-converting Phosphors in Optical Thermometry[J].Journal of Luminescence,2017,187:368-377.
[66] J.K.Cao,D.K.Xu,F.F.Hu,et al.Transparent Sr0.84Lu0.16F2.16:Yb3+,Er3+Glass Ceramics:Elaboration,Structure,Up-conversion Properties and Applications[J].Journal of the European Ceramic Society,2018,38(7):2753-2758.
[67] X.F.Wang,Y.Wang,L.S.Jin.Controlling Optical Temperature Detection of Ca3Al2O6:Yb3+,Er3+Phosphors through Doping[J].Journal of Alloys and Compounds,2019,773:393-400.
[68]王承遇,陶瑛.玻璃材料手册[M].北京:化学工业出版社,2008.
[69]陈国华.低温共烧玻璃陶瓷材料的制备及性能、机理研究[D].长沙:中南大学,2006.
[70] C.Basavapoornima,K.Lingann,C.R.Kesavulu,et al.Spectroscopic and Pump Power Dependent Up-conversion Studies of Er3+-doped Lead Phosphate Glasses for Photonic Applications[J].Journal of Alloys and Compounds,2017,199:959-968.
[71] L.Q.Liao,S.Jiang,S.S.Zhou,et al.Enhanced Up-converted Emission in Yb3+/Er3+Co-doped GdPO4 Transparent Glass Ceramics[J].Optics Communications,2014,326:130-133.
[72] F.F.Hu,X.T.Wei,Y.G.Qin,et al.Yb3+/Tb3+Co-doped GdPO4 Transparent Magnetic Glass-ceramics for Spectral Conversion[J].Journal of Alloys and Compounds,2016,674:162-167.
[73] M.Y.Ding,M.Zhang,C.H.Lu.Yb3+/Tm3+/Ho3+Tri-doped YPO4 Submicroplates:A Promising Optical Thermometer Operating in the First Biological Window[J].Materials Letters,2017,209:52-55.
[74] J.Zhang,Y.Q.Zhang,X.M.Jiang.Investigations on Up-conversion Luminescence of K3Y(PO4)2:Yb3+-Er3+/Ho3+/Tm3+Phosphors for Optical Temperature Sensing[J].Journal of Alloys and Compounds,2018,748:438-445.
[75]陈国华,刘心宇.低温烧结玻璃/陶瓷复合材料的微结构及性能[J].硅酸盐学报,2006,34(8):956-961.
[76]陈国华,刘心宇.堇青石基玻璃陶瓷研究进展[J].玻璃与搪瓷,2002,30(5):53-58.
[77]郭亮,陈国华.硼酸铝/硼玻璃复合材料制备及性能[C].2006年全国功能材料学术年会,2006.
[78] 唐林江,陈国华.低温烧结玻璃陶瓷复合材料的性能[C].中国功能材料及其应用学术会议,2007.