[1]王启予,田莲花.Mn离子激活的植物照明用荧光粉的研究进展[J].延边大学学报(自然科学版),2023,(03):268-274.
 WANG Qiyu,TIAN Lianhua.Research progress in improving luminescence intensity with Mn ion activated phosphors for plant - lighting[J].Journal of Yanbian University,2023,(03):268-274.
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Mn离子激活的植物照明用荧光粉的研究进展

参考文献/References:

[1] FANG S, LANG T, CAI M, et al.Light keys open locks of plant photoresponses: a review of phosphors for plant cultivation LEDs [J].J Alloys Compd, 2022,902:163825.
[2] 张云鹏.LED农业照明效益分析及推广建议[J].节能与环保,2021(12):34 - 35.
[3] DHOBLE S J, PRIYA R, DHOBLE N S, et al.Short review on recent progress in Mn4+ - activated oxide phosphors for indoor plant light - emitting diodes [J].Luminescence, 2021,36(3):560 - 575.
[4] BRIK M G, CAMARDELLO S J, SRIVASTAVA A M.Influence of covalency on the Mn4+ 2Eg4A2g emission energy in crystals [J].ECS J Solid State Sci Technol, 2015,4(3):39 - 43.
[5] ARUNKUMAR P, CHO H B, GIL K H, et al.Probing molecule - like isolated octahedra via phase stabilization of zero - dimensional cesium lead halide nanocrystals [J].Nat Commun, 2018,9(1):4691.
[6] BANERJEE A, SHILINA Y, ZIV B, et al.On the oxidation state of manganese ions in Li - ion battery electrolyte solutions [J].J Am Chem Soc, 2017,139(5):1738 - 1741.
[7] LEE J, KITCHAEV D A, KWON D H, et al.Reversible Mn2+/Mn4+ double redox in lithium - excess cathode materials [J].Nature, 2018,556(7700):185 - 190.
[8] OMRI K, LAHOULI R, EL M L.Microstructure and electrical properties of silica - Zn2SiO4 - Mn glass - ceramics as composite for optoelectronic devices [J].Results Phys, 2019,12:2141 - 2145.
[9] ZHANG Y, WU Z, GENG D, et al.Nanospheres: Full color emission in ZnGa2O4: simultaneous control of the spherical morphology, luminescent, and electric properties via hydrothermal approach [J].Adv Funct Mater, 2014,24(42):6566 - 6566.
[10] DU M H.Mn4+ emission in pyrochlore oxides [J].J Lumin, 2015,157:69 - 73.
[11] KAWANO T, SUEHIRO T, SATO T, et al.Preparation, crystal structure and photoluminescence of Mn2+ - doped magnesium pyroborates solid solutions,(Mg1-xMnx)2B2O5[J].J Lumin, 2010,130(11):2161 - 2165.
[12] CAO R, SHI Z, QUAN G, et al.Preparation and luminescence properties of Li2MgZrO4:Mn4+ red phosphor for plant growth [J].J Lumin, 2017,188:577 - 581.
[13] CHEN H, LIN H, HUANG Q, et al.A novel double - perovskite Gd2ZnTiO6:Mn4+ red phosphor for UV - based w - LEDs: structure and luminescence properties [J].J Mater Chem C, 2016,4(12):2374 - 2381.
[14] HUANG X, GUO H.Finding a novel highly efficient Mn4+ - activated Ca3La2W2O12 far - red emitting phosphor with excellent responsiveness to phytochrome PFR: towards indoor plant cultivation application [J].Dyes Pigments, 2018,152:36 - 42.
[15] LIANG S, SHANG M, LIAN H, et al.Deep red MGe4O9:Mn4+(M=Sr,Ba)phosphors: structure, luminescence properties and application in warm white light emitting diodes [J].J Mater Chem C, 2016,4(26):6409 - 6416.
[16] LU Z, HUANG T, DENG R, et al.Double perovskite Ca2GdNbO6:Mn4+ deep red phosphor: potential application for warm W - LEDs [J].Superlattices and Microstructures, 2018,117:476 - 487.
[17] PENG Q, CAO R, YE Y, et al.Photoluminescence properties of broadband deep - red - emitting Na2MgAl10O17:Mn4+ phosphor [J].J Alloys Compd, 2017,725:139 - 144.
[18] ZHANG S, HU Y.Photoluminescence spectroscopies and temperature - dependent luminescence of Mn4+ in BaGe4O9 phosphor [J].J Lumin, 2016,177:394 - 401.
[19] GENG X, XIE Y, HU X, et al.Greatly enhanced deep - red luminescence performance of Ca2InSbO6:Mn4+ phosphor via multiple optimization strategies [J].Mater Today Chem, 2022,26:101006.
[20] ZHANG A Q, SUN Z, JIA M C, et al.Sm3+ - doped niobate orange - red phosphors with a double - perovskite structure for plant cultivation and temperature sensing [J].J Alloys Compd, 2021,889:161671.
[21] LI G, LU X, MAO Q, et al.Suppression of charge imbalance via Li+ - Mn4+ co - incorporated Sr2YSbO6 red phosphors for warm w - LEDs [J].Mater Today Chem, 2022,23:100744.
[22] PAN Y X, LIU G K.Influence of Mg2+ on luminescence efficiency and charge compensating mechanism in phosphor CaAl12O19:Mn4+ [J].J Lumin, 2011,131(3):465 - 468.
[23] CAO R, LUO W, XU H, et al.Luminescence property and emission enhancement of YbAlO3:Mn4+ red phosphor by Mg2+ or Li+ ions [J].Opt Mater, 2016,53:169 - 173.
[24] SUN Q, WANG S, DEVAKUMAR B, et al.CaYAlO4:Mn4+,Mg2+: an efficient far - red - emitting phosphor for indoor plant growth LEDs [J].J Alloys Compd, 2019,785:1198 - 1205.
[25] WANG B, LIN H, HUANG F, et al.Non - Rare - Earth BaMgAl10-2xO17:x Mn4+,x Mg2+: a Narrow - Band red phosphor for use as a high - power warm w - LED [J].Chem Mater, 2016,28(10):3515 - 3524.
[26] WANG S, SUN Q, DEVAKUMAR B, et al.Novel Ca2GdTaO6:Mn4+,M(M=Li+,Na+,K+, and Mg2+)red phosphors for plant cultivation light - emitting diodes: synthesis and luminescence properties [J].J Lumin, 2019,214:116525.
[27] YANG Z, BU H, ZHANG F, et al.Enhanced luminescence performances of Sr2YTaO6:Mn4+ narrow red phosphor by Rn+(Li+,Na+,Ca2+,Mg2+)ions [J].J Lumin, 2021,235:118030.
[28] ZHOU L, SHEN C, SHEN L, et al.Enhanced luminescence performances of Mn4+:Y3Al5O12 red phosphor by ions of Rn2+(Be2+,Mg2+,Sr2+,Ba2+)[J].J Alloys Compd, 2018,769:686 - 693.
[29] ZHU Y, QIU Z, AI B, et al.Significant improved quantum yields of CaAl12O19:Mn4+ red phosphor by co - doping Bi3+ and B3+ ions and dual applications for plant cultivations [J].J Lumin, 2018,201:314 - 320.
[30] SUN L, DEVAKUMAR B, LIANG J, et al.Simultaneously enhanced far - red luminescence and thermal stability in Ca3Al4ZnO10:Mn4+ phosphor via Mg2+ doping for plant growth lighting [J].J Alloys Compd, 2019,785:312 - 319.
[31] FANG S, LANG T, HAN T, et al.Zero - thermal - quenching of Mn4+ far - red - emitting in LaAlO3 perovskite phosphor via energy compensation of electrons’ traps [J].Chem Eng J, 2020,389:124297.
[32] ZHOU C, ZHANG Y, ZHU J, et al.Enhanced luminescence performances of BaLaMgTaO6:Mn4+ red phosphor by Bi3+, Ca2+ doping for indoor plant lighting supplementary LED [J].Spectrochim Acta A Mol Biomol Spectrosc, 2022,268:120655.
[33] FU L, YANG Y, ZHANG Y, et al.The novel Sr3LiSbO6:Mn4+,Ca2+ far - red - emitting phosphors with over 95% internal quantum efficiency for indoor plant growth LEDs [J].J Lumin, 2021,237:118165.
[34] ZHU B, YANG Q, ZHANG W, et al.A high sensitivity dual - mode optical thermometry based on charge compensation in ZnTiO3:M(M=Eu3+,Mn4+)hexagonal prisms [J].Spectrochim Acta A Mol Biomol Spectrosc, 2022,274:121101.
[35] WANG T H, LI Y J, LIU T, et al.NIR - NIR upconverting optical temperature sensing based on the thermally coupled levels of Yb3+ - Tm3+ codoped Bi7F11O5 nanosheets [J].J Lumin, 2020,221:117034.
[36] CAO R, XU L, RAN Y, et al.Luminescence property improvement of Ba2LaSbO6:Mn4+ phosphor by using Dy3+ or H3BO3 [J].Physics Letters A, 2019,383(17):2102 - 2105.
[37] FANG Y, WANG C, ZHANG Y, et al.Preparation of far - red emitting Ba2YTaO6:Mn4+ phosphors for plant growth LEDs applications [J].Inorg Chem Commun, 2021,128:108568.
[38] YUAN L, JIN Y, XIONG G, et al.Flux - assisted low - temperature synthesis of Mn4+ - doped unusual broadband deep - red phosphors toward warm w - LEDs [J].J Alloys Compd, 2021,870:159394.
[39] HU M, LIAO C, XIA L, et al.Low temperature synthesis and photoluminescence properties of Mn4+ - doped La2MgTiO6 deep - red phosphor with a LiCl flux [J].J Lumin, 2019,211:114 - 120.
[40] ZHANG G, YIN Y, WANG Y, et al.Tunable blue - red dual emission via energy transfer in Na4CaSi3O9:Ce3+,Mn2+ phosphors for plant growth LED [J].J Lumin, 2021,235:118029.
[41] HUANG C H, CHEN T M.A novel single - composition trichromatic white - light Ca3Y(GaO)3(BO3)4:Ce3+,Mn2+,Tb3+ phosphor for UV - light emitting diodes [J].The J Phys Chem C, 2011,115(5):2349 - 2355.
[42] PASINSKI D, SOKOLNICKI J.Broadband orange phosphor by energy transfer between Ce3+ and Mn2+ in Ca3Al2Ge3O12 garnet host [J].J Alloys Compd, 2019,786:808 - 816.
[43] YONESAKI Y, TAKEI T, KUMADA N, et al.Sensitized red luminescence from Ce3+,Mn2+ - doped glaserite - type alkaline - earth silicates [J].J Solid State Chem, 2010,183(6):1303 - 1308.
[44] AITMELLAL O, OUFNI L, MESSOUS M Y, et al.The influence of Zr4+ doping on the structural and photoluminescence properties of LaPO4:Ce3+/Mn2+ phosphors [J].J Lumin, 2022,251:119226.
[45] WANG F, JIN Y, LIU Y, et al.Tunable luminescence of Na3YSi3O9:Ce3+,Mn2+ via efficient energy transfer for white LEDs [J].J Lumin, 2019,206:227 - 233.
[46] PAN Z, CHEN J, WU H, et al.Red emission enhancement in Ce3+/Mn2+ co - doping suited garnet host MgY2Al4SiO12 for tunable warm white LED [J].Opt Mater, 2017,72:257 - 264.
[47] GONG W, LUO J, ZHOU W, et al.Thermal - stable blue - red dual - emitting Na2Mg2Si6O15:Eu2+,Mn2+ phosphor for plant growth lighting [J].J Lumin, 2021,239:118372.
[48] YAN J, ZHANG Z W, WEN D W, et al.Crystal structure and photoluminescence tuning of novel single - phase Ca8ZnLu(PO4)7:Eu2+,Mn2+ phosphors for near - UV converted white light - emitting diodes [J].J Mater Chem C, 2019,7:8374 - 8382.
[49] DONG R, LIU W, SONG Y, et al.A promising single - phase, color - tunable phosphor(Ba0.9Sr0.1)9Lu2Si6O24:Eu2+,Mn2+ for near - ultraviolet white - light - emitting diodes [J].J Lumin, 2019,214:116585.
[50] SUN Z, ZHU Z, LUO J, et al.High - efficient and thermal - stable Ca19Zn2(PO4)14:Eu2+,Mn2+ blue - red dual - emitting phosphor for plant cultivation LEDs [J].J Alloys Compd, 2019,811:151956.
[51] MUNIRATHNAM K, MALLIKARJUNA K, VIJAYA R, et al.Spectral change and far - red emission of Mn2+ ions co - doped NaSrB5O9:Dy3+ luminescence material for plant growth LEDs [J].J Rare Earths, 2022,40(2):218.
[52] GUO L, LI T, ZHU C, et al.Variable luminnescence chromaticity and energy transfer in CaZnOS:Pr3+,Mn2+ by ultraviolet and blue excitations [J].J Solid State Chem, 2023,317:123697.
[53] LI X, FENG Y, WANG L, et al.Bi3+ → Mn2+ energy transfer and tunable luminescence in Ba9La2Si6O24:Bi3+/Mn2+ phosphors [J].Opt Mater, 2022,131:112593.
[54] YAN S, SUN Y, ZHENG Z.Roles of Nd3+ in enhancing Mn2+ - Activated SrZn2(PO4)2 long persistent phosphor [J].J Lumin, 2023,254:119475.
[55] FENG P, WANG Y, DING S.Theoretical calculations and investigation on properties and defect states in SrMgGe2O6:Mn2+,Sm3+ [J].Chem Eng J, 2022,450:137820.
[56] SATO Y, KATO H, KOBAYASHI M, et al.Tailoring of deep - red luminescence in Ca2SiO4:Eu2+ [J].Angew Chem Int Ed, 2014,53(30):7756 - 7759.
[57] ZHANG Y, LI X, LI K, et al.Crystal - site engineering control for the reduction of Eu3+ to Eu2+ in CaYAIO4: structure refinement and tunable emission properties [J].ACS Appl Mater Interfaces, 2015,7(4):2715 - 2725.
[58] WAKUI Y, SHAN Y J, TEZUKA K, et al.Crystal - site engineering approach for preparation of MgB2O4:Mn2+,Mn4+(B=Al,Ga)phosphors: control of green/red luminescence properties [J].Mater Res Bull, 2017,90:51 - 58.
[59] DAI P, XU Z, YU X, et al.Mesoporous hollow Zn2SiO4:Mn2+ nanospheres: the study of photoluminescence and adsorption properties [J].Mater Res Bull, 2015,61:76 - 82.
[60] PITALE S S, KUMAR V, NAGPURE I M, et al.Luminescence characterization and electron beam induced chemical changes on the surface of ZnAl2O4:Mn nanocrystalline phosphor [J].Appl Surf Sci, 2011,257(8):3298 - 3306.
[61] SAI Q, XIA C, RAO H, et al.Mn,Cr - co - doped MgAl2O4 phosphors for white LEDs [J].J Lumin, 2011,131(11):2359 - 2364.
[62] TOMITA A, SATO T, KAWABE Y, et al.Luminescence channels of manganese - doped spinel [J].J Lumin, 2004,109:19 - 24.
[63] TSAI M T, CHANG Y S, HUANG I B, et al.Luminescent and structural properties of manganese - doped zinc aluminate spinel nanocrystals [J].Ceram Int, 2013,39(4):3691 - 3697.
[64] ZHANG D, WANG C, LIU Y, et al.Green and red photoluminescence from ZnAl2O4:Mn phosphors prepared by sol - gel method [J].J Lumin, 2012,132(6):1529 - 1531.
[65] ZHONG R, ZHANG J, WEI H, et al.The different luminescent characteristics of MgAl2O4:Mn2+between phosphor powder and nanoparticles [J].Chem Phys Lett, 2011,508(4):207 - 209.
[66] COSTA G K B, PEDRO S S, CARVALHO I C S, et al.Preparation, structure analysis and photoluminescence properties of MgGa2O4:Mn2+ [J].Opt Mater, 2009,31(11):1620 - 1627.
[67] CHI F, JIANG B, ZHAO Z, et al.Multimodal temperature sensing using Zn2GeO4:Mn2+ phosphor as highly sensitive luminescent thermometer [J].Sens Actuators B, 2019,296:126640.
[68] PENG M, HONG G.Reduction from Eu3+ to Eu2+ in BaAl2O4:Eu phosphor prepared in an oxidizing atmosphere and luminescent properties of BaAl2O4:Eu [J].J Lumin, 2007,127(2):735 - 740.
[69] SEVIC D, RABASOVIC M S, KRIZAN J, et al.YVO4:Eu3+ nanopowders: multi - mode temperature sensing technique [J].J Phys D Appl Phys, 2019,53(1):015106.
[70] ZHU Y, LI C, DENG D, et al.A high - sensitivity dual - mode optical thermometry based on one - step synthesis of Mn2+:BaAl12O19- Mn4+:SrAl12O19 solid solution phosphors [J].J Alloys Compd, 2021,853:157262.
[71] MCNICOL B D, POTT G T.Luminescence of Mn ions in ordered and disordered LiAl5O8 [J].J Lumin, 1973,6(4):320 - 334.
[72] 周爱萍,张化福,臧永丽.ZnAl2O4:Mn纳米晶的红绿发光[J].材料科学与工程学报,2012,30(3):432 - 435.

备注/Memo

收稿日期: 2022-08-23
基金项目: 吉林省教育厅“十三五”科学技术项目(JJKH20180893KJ)
第一作者: 王启予(1998—),女,硕士研究生,研究方向为发光学.
通信作者: 田莲花(1972—),女,博士,教授,研究方向为发光学.

更新日期/Last Update: 2023-09-20