[1]李強(qiáng),鄭靜霞,楊永珍,等.激光照明用熒光材料的研究進(jìn)展[J].中國(guó)材料進(jìn)展,2023,42(04):343-352.[doi:10.7502/j.issn.1674-3962.202106019]
LI Qiang,ZHENG Jingxia,YANG Yongzhen,et al.Research Progress of Fluorescent Materials for Laser Lighting[J].MATERIALS CHINA,2023,42(04):343-352.[doi:10.7502/j.issn.1674-3962.202106019]
點(diǎn)擊復(fù)制
激光照明用熒光材料的研究進(jìn)展(
)
中國(guó)材料進(jìn)展[ISSN:1674-3962/CN:61-1473/TG]
- 卷:
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42
- 期數(shù):
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2023年第04期
- 頁碼:
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343-352
- 欄目:
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- 出版日期:
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2023-04-30
文章信息/Info
- Title:
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Research Progress of Fluorescent Materials for Laser Lighting
- 文章編號(hào):
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1674-3962(2023)04-0343-10
- 作者:
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李強(qiáng)1; 鄭靜霞1; 楊永珍1; 劉旭光1; 2; 許并社1
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1. 太原理工大學(xué) 新材料界面科學(xué)與工程教育部重點(diǎn)實(shí)驗(yàn)室,山西 太原 030024
2. 太原理工大學(xué)材料科學(xué)與工程學(xué)院,山西 太原 030024
- Author(s):
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LI Qiang1; ZHENG Jingxia1; YANG Yongzhen1; LIU Xuguang1; 2; XU Bingshe1
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1.Key Laboratory of Interface Science and Engineering in Advanced Materials Ministry of Education,Taiyuan University of Technology, Taiyuan 030024, China
2.College of Materials Science and Engineering, Taiyuan University of Technology, Taiyuan 030024, China
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- 關(guān)鍵詞:
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激光; 高亮度; 熒光材料; 照明; 光熱穩(wěn)定性
- Keywords:
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laser; high brightness; fluorescent materials; lighting; photothermal stability
- 分類號(hào):
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TB34
- DOI:
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10.7502/j.issn.1674-3962.202106019
- 文獻(xiàn)標(biāo)志碼:
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A
- 摘要:
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半導(dǎo)體激光器具有亮度高、傳輸距離遠(yuǎn)等優(yōu)點(diǎn),特別適用于特殊照明領(lǐng)域(如激光車燈、投影顯示等)。簡(jiǎn)述激光照明的實(shí)現(xiàn)方式以及目前存在的主要問題,重點(diǎn)綜述稀土、半導(dǎo)體、碳點(diǎn)3種熒光材料在激光照明中的研究進(jìn)展。稀土作為目前最常用的激光照明用熒光材料,主要有稀土熒光粉、熒光陶瓷、熒光玻璃3種形式,具有光熱穩(wěn)定性高等優(yōu)點(diǎn),但資源不可再生和價(jià)格昂貴等限制了其進(jìn)一步應(yīng)用;半導(dǎo)體熒光材料主要有以CdSe和ZnS為代表的第二代半導(dǎo)體量子點(diǎn)材料、以SiC和AlN為代表的第三代半導(dǎo)體材料和鈣鈦礦材料,第二代半導(dǎo)體量子點(diǎn)材料和第三代半導(dǎo)體材料具有發(fā)光效率高、性能穩(wěn)定等優(yōu)點(diǎn),但受限于成本和工藝,鈣鈦礦材料具有帶隙可調(diào)、可獲得穩(wěn)定的自發(fā)輻射等優(yōu)點(diǎn),但含有毒性元素且對(duì)環(huán)境的高度敏感性導(dǎo)致其穩(wěn)定性較差;碳點(diǎn)熒光材料具有發(fā)光波長(zhǎng)可調(diào)、低毒性等優(yōu)點(diǎn),主要有光轉(zhuǎn)換材料和增益介質(zhì)2種形式,但目前在激光下的熱穩(wěn)定性欠缺。最后,對(duì)未來激光照明用熒光材料的發(fā)展前景進(jìn)行展望。
- Abstract:
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With the advantages of high brightness and long transmission distance, semiconductor laser is especially suitable for special lighting fields (such as laser car lights, projection display). In this review, the realization methods of laser lighting and its main problems are briefly discussed. The research progress of rare earth, semiconductor, and carbon dots fluorescent material in laser lighting is emphatically summarized. As the most commonly used fluorescent material for laser illumination at present, rare earth fluorescent materials mainly include rare earth phosphors, fluorescent ceramic, and fluorescent glasses, which have high photo-thermal stability. But their further application is restricted because of their non-renewable resources and high price. Semiconductor fluorescent materials mainly include the second-generation semiconductor quantum dot materials represented by CdSe and ZnS, the third-generation semiconductor materials represented by SiC and AlN, and perovskite materials. The second-generation semiconductor quantum dot materials and third-generation semiconductor materials have the advantages of high luminous efficiency and stable performance, but are limited by their cost and process. Perovskite materials exhibit adjustable band gap and stable spontaneous radiation, however, they contain toxic elements and are highly sensitive to the environment resulting in poor stability. Carbon dots phosphors with tunable emission wavelength and low toxicity, are mainly in two forms of light conversion materials and gain media, nevertheless, their thermal stability under laser is poor. At last, the development of fluorescent materials for laser lighting in the future is prospected.
參考文獻(xiàn)/References:
\[1\]DUBEY A K,KUMAR V,GUPTA M,et al.Laser Physics Letters\[J\],2020,17(12):126001.
\[2\]LI S X,WANG L,HIROSAKI N,et al.Laser & Photonics Review\[J\],2018,12(12):1800173.
\[3\]徐競(jìng),蔣福春,柴廣躍,等.光源與照明\[J\],2017,4:11-13.
XU J,JIANG F C,CHAI G Y,et al.Light Source and Illumination\[J\],2017,4:11-13.
\[4\]ZHANG R H,CHUNG H S H.IEEE Transactions on Power Electronics\[J\],2015,30(12):6948-6965.
\[5\]KWON S B,KIM B Y,JANG I S,et al.Current Applied Physics\[J\],2020,20(7):862-865.
\[6\]楊晶晶.半導(dǎo)體激光白光照明關(guān)鍵技術(shù)研究\[D\].長(zhǎng)春:長(zhǎng)春理工大學(xué),2015.
YANG J J.Research on Key Technology of Semiconductor Laser White Light Illumination\[D\]. Changchun:Changchun University of Science and Technology,2015.
\[7\]WANG J,ZHAO X J,CAI Y X,et al.IEEE Transactions on Components Packaging & Manufacturing Technology\[J\],2015,5(5):641-649.
\[8\]DING X,LI M,LIANG Y,et al.International Communications in Heat and Mass Transfer\[J\],2020,114:104552.
\[9\]XU G,F(xiàn)UJII K I,NAKAYAMA S.The Review of Laser Engineering\[J\],1997,25(6):431-433.
\[10\]TRIVELLIN N,YUSHCHENKO M,BUFFOLO M,et al.Materials\[J\],2017,10(10):1166-1185.
\[11\]WU H J,HAO Z D,PAN G H,et al.Journal of the European Ceramic Society\[J\],2020,40(6):2439-2444.
\[12\]康健,張樂,甄方正,等.化學(xué)進(jìn)展\[J\],2019,31(2/3):322-336.
KANG J,ZHANG L,ZHEN F Z,et al.Progress in Chemical\[J\],2019,31(2/3):322-336.
\[13\]LIU W N,YANG T,CHEN J H,et al.Physical Chemistry Chemical Physics\[J\],2016,18(39):27572-27576.
\[14\]HAN T,VAGANOV V,CAO S X,et al.Scientific Reports\[J\],2017,7(1):45944.
\[15\]SUN Q,WANG S Y,SUN L L,et al.Materials Today Energy\[J\],2020,17:100448.
\[16\]夏夢(mèng)玲,劉超,趙修建,等.中國(guó)材料進(jìn)展\[J\],2017,36(7/8):541-549.
XIA M L,LIU C,ZHAO X J,et al.Materials China\[J\],2017,36(7/8):541-549.
\[17\]劉博林.稀土發(fā)光材料的研究進(jìn)展\[D\].長(zhǎng)春:東北師范大學(xué),2007.
LIU B L.Research Progress of Rare Earth Luminescent Materials\[D\].Changchun:Northeast Normal University,2007.
\[18\]LIU J,KACZMAREK A M,DEUN R V,et al.Chemical Society Reviews\[J\],2018,47(19):7225-7238.
\[19\]NEACSU I A,STOICA E A,VASILE B S,et al.Nanomaterials\[J\],2019,9(2):239-260.
\[20\]ZHANG H,ZHANG H Q,PAN A Z,et al.Advanced Materials Technologies\[J\],2020,6(1):2000648.
\[21\]YANG C,LI X,LIU Q S,et al.Journal of Materials Science: Materials in Electronics\[J\],2020,31(2):1057-1064.
\[22\]YUAN R,HUANG M,ZHENG F,et al.Journal of Materials Chemistry C\[J\],2019,7(42):13070-13079.
\[23\]AUZEL F.Journal of Luminescence\[J\],2019, 223:116900.
\[24\]BOONSIN R,CHADEYRON G,ROBLIN J P,et al.Journal of Materials Chemistry C\[J\],2015,3(37):9580-9587.
\[25\]FU Y T,ZHAO L J,GUO Y,et al.Journal of Luminescence\[J\],2019,217:116790.
\[26\]SONG X,CHANG M H,PECHT M.JOM\[J\],2013,65(10):1276-1282.
\[27\]KUMAR V,NTWAEABORWA O M,SOGA T,et al.ACS Photonics\[J\],2017,4(11):2613-2637.
\[28\]VERMA S,VERMA K,KUMAR D,et al.Physica B:Condensed Matter\[J\],2018,535:106-113.
\[29\]ZHANG K Y,KLEIT A N,NIETO A.Renewable and Sustainable Energy Reviews\[J\],2017,77:899-915.
\[30\]ZHONG T,GOLDNER P.Nanophotonics\[J\],2019,8(11):2003-2015.
\[31\]RICCI P C.Crystals\[J\],2020,10(7):559-585.
\[32\]XU Y,CHEN L H,LI Y Z,et al.Applied Physics Letters\[J\],2008,92(2):021129.
\[33\]DENAULT K A,CANTORE M,NAKAMURA S,et al.AIP Advances\[J\],2013,3(7):072107.
\[34\]ALWAISAWY S,JADWISIENCZAK W M,WRIGHT J,et al.Journal of Luminescence\[J\],2016,169:196-203.
\[35\]AKIYAMA J,SATO Y,TAIRA T.Optics Letters\[J\],2010,35(21):3598-3600.
\[36\]TANABE S,HAYASHI H,HANADA T,et al.Optical Materials\[J\],2002,19(3):343-349.
\[37\]SONG Y H,JI E K,JEONG B W,et al.Scientific Reports\[J\],2016,6:31206.
\[38\]LI S X,TANG D M,TIAN Z F,et al.Journal of Materials Chemistry C\[J\],2017,5(5):1042-1051.
\[39\]COZZAN C,LHEUREUX G,ODEA N,et al.ACS Applied Materials & Interfaces\[J\],2018,10(6):5673-5681.
\[40\]KAWAMURA S,IKEDA T,JIN W G.Journal of the Physical Society of Japan\[J\],2020,89(5):055002.
\[41\]ZHANG X J,YU J B,WANG J,et al.ACS Photonics\[J\],2017,4(4):986-995.
\[42\]WANG B,LI D S,SHEN L F,et al.Optical Materials Express\[J\],2019,9(4):1749-1762.
\[43\]ROIZ M,MONAKHOV A M,KUNITSYNA E,et al.Journal of Applied Physics\[J\],2020,127(17):173105.
\[44\]ZHANG L P,JARONIEC M.Applied Surface Science\[J\],2017,430(1):2-17.
\[45\]LIU W,LUSTIG W P,LI J.EnergyChem\[J\],2019,1(2): 100008.
\[46\]XU J,HU B F,XU C,et al.Optical Materials\[J\],2018,86:286-290.
\[47\]WANG W C,WANG H Y,CHEN T Y,et al.Nanophotonics\[J\],2019,8(12):2189-2201.
\[48\]AMJAD A A,AMJAD R T,MANE M,et al.Applied Optics\[J\],2020,59(17):5197-5204.
\[49\]CHEN Z L,LIU Z Q,WEI T B,et al.Advanced Materials\[J\],2019,31(23):1807345.
\[50\]WIEG A,PENILLA E H,HARDIN C,et al.APL Materials\[J\],2016,4(12):126105.
\[51\]WANG S C,JI L F,LI L,et al.Scientific Reports\[J\],2018,8:257-266.
\[52\]CHEN J,WU Y,LI X M,et al.Advanced Materials Technologies\[J\],2017,2(10):1700132.
\[53\]HUANG C Y,ZOU C,MAO C Y,et al.ACS Photonics\[J\],2017,4(9):2281-2289.
\[54\]SUTHERLAND B R,HOOGLAND S,ADACHI M M,et al.ACS Nano\[J\],2014,8(10):10947-10952.
\[55\]ZHU H M,F(xiàn)U Y P,MENG F,et al.Nature Materials\[J\],2015,14:636-642.
\[56\]XING J,LIU X F,ZHANG Q,et al.Nano Letters\[J\],2015,15(7):4571-4577.
\[57\]KONG W M,LI G H,LIANG Q B,et al.Physica E LowDimensional Systems and Nanostructures\[J\],2017,97:130-135.
\[58\]ZHANG Q,HA S T,LIU X F,et al.Nano Letters\[J\],2014,14(10):5995-6001.
\[59\]WANG K Y,SUN W Z,LI J K,et al.ACS Photonics\[J\],2016,3(6):1125-1130.
\[60\]DONG H Y,ZHANG C H,LIU X L,et al.Chemical Society Reviews\[J\],2020,49:951-982.
\[61\]王占國(guó).中國(guó)材料進(jìn)展\[J\],2009,28(1):26-30.
WANG Z G.Materials China\[J\],2009,28(1):26-30.
\[62\]劉曉惠.碳點(diǎn)的結(jié)構(gòu)調(diào)控及其光催化氧化性能研究\[D\].開封:河南大學(xué),2018.
LIU X H.Structure Control of Carbon Dot and Its Photocatalytic Oxidation Performance\[D\].Kaifeng:Henan University,2018.
\[63\]曲松楠,孫銘鴻,田震,等.發(fā)光學(xué)報(bào)\[J\],2019,40(5):557-580.
QU S N,SUN M H,TIAN Z,et al.Journal of Luminescence\[J\],2019,40(5):557-580.
\[64\]ZHOU Z J,TIAN P F,LIU X Y,et al.Advanced Science \[J\], 2018,5(8):1800369.
\[65\]SONG X Q,GUO Q Y,CAI Z L,et al.Ceramics International\[J\],2019,45(14):17387-17394.
\[66\]楊永珍,何品一,鄭靜霞,等.一種石墨烯量子點(diǎn)熒光薄膜及其制備方法:CN111170311A\[P\].2020-02-28.
YANG Y Z,HE P Y,ZHENG J X,et al.A Graphene Quantum Dot Fluorescent Film and Its Preparation Method:CN111170311A\[P\].2020-02-28.
\[67\]HE P Y,YANG S,LIU X H,et al.Journal of Luminescence\[J\],2021,238:118275.
\[68\]CHEN B,F(xiàn)ENG J C.The Journal of Physical Chemistry C\[J\],2015,119(14):7865-7872.
\[69\]ZHANG Y Q,HU Y S,LIN J,et al.ACS Applied Materials & Interfaces\[J\],2016,8(38):25454-25460.
\[70\]QU S N,LIU X Y,GUO X Y,et al.Advanced Functional Materials\[J\],2014,24(18):2689-2695.
\[71\]LIU H Z,WANG F,WANG Y P,et al.ACS Applied Materials & Interfaces\[J\],2017,9(21):18248-18253.
\[72\]許并社,許佳聰,鄭靜霞,等.科學(xué)通報(bào)\[J\],2019,64(14):1441-1455.
XU B S,XU J C,ZHENG J X,et al.Chinese Science Bulletin\[J\],2019,64(14):1441-1455.
\[73\]RIAZ R,ALI M,MAIYALAGAN T,et al.Applied Surface Science\[J\],2019,483:425-431.
備注/Memo
- 備注/Memo:
-
收稿日期:2021-06-20修回日期:2021-09-07
基金項(xiàng)目:國(guó)家自然科學(xué)基金資助項(xiàng)目(51972221);山西省回國(guó)
留學(xué)人員科研資助項(xiàng)目(2020-051,HGKY2019027)
第一作者:李強(qiáng),男,1995年生,碩士研究生
通訊作者:鄭靜霞,女,1987年生,講師,博士,
Email: zhengjingxia@tyut.edu.cn
楊永珍,女,1969年生,教授,博士生導(dǎo)師,
Email: yyztyut@126.com
更新日期/Last Update:
2023-03-22