Hostname: page-component-586b7cd67f-tf8b9 Total loading time: 0 Render date: 2024-11-26T12:17:09.790Z Has data issue: false hasContentIssue false
  • English
  • Français

Enhanced Photoluminescence Properties of Low-Dimensional Eu3+-Activated Y4Al2O9 Phosphor Compared to Bulk for Solid-State Lighting Applications and Latent Fingerprint Detection-Based Forensic Applications

Published online by Cambridge University Press:  26 April 2019

Antika Das ,
Subhajit Saha ,
Karamjyoti Panigrahi ,
Uttam Kumar Ghorai  and
Kalyan Kumar Chattopadhyay
Antika Das
Affiliation:
School of Materials Science and Nanotechnology, Jadavpur University, Kolkata-700032, West Bengal, India
Subhajit Saha
Affiliation:
School of Materials Science and Nanotechnology, Jadavpur University, Kolkata-700032, West Bengal, India
Karamjyoti Panigrahi
Affiliation:
School of Materials Science and Nanotechnology, Jadavpur University, Kolkata-700032, West Bengal, India
Uttam Kumar Ghorai
Affiliation:
Department of Industrial Chemistry and Applied Chemistry, Swami Vivekananda Research Centre, Ramakrishna Mission Vidyamandira, Belurmath, Howrah-711202, West Bengal, India
Kalyan Kumar Chattopadhyay*
Affiliation:
School of Materials Science and Nanotechnology, Jadavpur University, Kolkata-700032, West Bengal, India
*
*Author for correspondence: Kalyan Kumar Chattopadhyay, E-mail: [email protected]
Get access

Abstract

In recent years, nanoscale phosphors have become vital in optoelectronic applications and to understand the improved performance of nanophosphors over bulk material, detailed investigation is essential. Herein, trivalent europium-activated Y4Al2O9 phosphors were developed by solid-state reaction and solvothermal reaction methods and their performance as a function of their dimension was studied for various applications. Under 394 nm optical excitation, the photoluminescence (PL) emission, excited state lifetime of the nanophosphor, exhibits greater performance than its bulk counterpart. The homogeneous spherical structure of the nanophosphors as compared with solid lumps of bulk phosphors is the basis for almost 40% of the enhancement in nanophosphors' intense red emission compared to the bulk. Moreover, the thermal stability of the nanophosphor is much better than the bulk phosphor, which clearly indicates a key advantage of nanophosphor. The superior performance of Eu3+-doped Y4Al2O9 nanophosphors over their bulk counterparts has been demonstrated for industrial phosphor-converted light-emitting diodes and visualization of latent fingerprint.

Keywords

bulk phosphorlatent fingerprint (LFP)nanophosphorphotoluminescence (PL) emissionsolid-state lighting (SSL)solid-state reactionsolvothermal
Type
Materials Applications
Information
Microscopy and Microanalysis , Volume 25 , Issue 6 , December 2019 , pp. 1422 - 1430
Copyright
Copyright © Microscopy Society of America 2019 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Algarra, M, Radotić, K, Kalauzi, A, Mutavdžić, D, Savić, A, Jiménez-Jiménez, J & Guerrero-González, JJ (2014). Fingerprint detection and using intercalated CdSe nanoparticles on non-porous surfaces. Anal Chim Acta 812, 228235.Google Scholar
Behren Von, J, Buuren Van, T, Zacharias, M, Chimowitz, EH & Fauchet, PM (1998). Quantum confinement in nanoscale silicon: The correlation of size with bandgap and luminescence. Solid State Commun 105(5), 317322.Google Scholar
Binnemans, K (2015). Interpretation of europium (III) spectra. Coord Chem Rev 295, 145.Google Scholar
Cheng, Z & Lin, J (2015). Synthesis and application of nanohybrids based on up converting nanoparticles and polymers. Macromol Rapid Commun 36(9), 790827.Google Scholar
Darshan, GP, Premkumar, HB, Nagabhushana, H, Sharma, SC, Prasad, BD & Prashantha, SC (2016). Neodymium doped yttrium aluminate synthesis and optical properties – A blue light emitting nanophosphor and its use in advanced forensic analysis. Dyes Pigm 134, 227233.Google Scholar
Deng, D, Yu, H, Li, Y, Hua, Y, Jia, G, Zhao, S & Xu, S (2013). Ca4(PO4)2O: Eu2+ red-emitting phosphor for solid-state lighting: Structure, luminescent properties and white light emitting diode application. J Mater Chem C 1(19), 31943199.Google Scholar
Dwivedi, J, Kumar, P, Kumar, A, Singh, VN, Singh, BP, Dhawan, SK & Gupta, BK (2014). A commercial approach for the fabrication of bulk and nano phosphors converted into highly efficient white LEDs. RSC Adv 4(98), 5493654947.Google Scholar
Fang, YC, Chu, SY, Kao, PC, Chuang, YM & Zeng, ZL (2011). Energy transfer and thermal quenching behaviors of CaLa2 (MoO4) 4: Sm3+, Eu3+ red phosphors. J Electrochem Soc 158(2), J1J5.Google Scholar
Geng, D, Li, G, Shang, M, Peng, C, Zhang, Y, Cheng, Z & Lin, J (2012). Nanocrystalline CaYAlO4: Tb3+/Eu3+ as promising phosphors for full-color field emission displays. Dalton Trans 41(10), 30783086.Google Scholar
Guo, N, You, H, Song, Y, Yang, M, Liu, K, Zheng, Y & Zhang, H (2010). White-light emission from a single-emitting-component Ca9Gd(PO4)7: Eu2+, Mn2+ phosphor with tunable luminescent properties for near-UV light-emitting diodes. J Mater Chem 20(41), 90619067.Google Scholar
Han, JY, Im, WB, Lee, GY & Jeon, DY (2012). Near UV-pumped yellow-emitting Eu2+-doped Na3K (Si1−x Alx)8O16±δ phosphor for white-emitting LEDs. J Mater Chem 22(18), 87938798.Google Scholar
Ju, M, Lu, C, Yeung, Y, Kuang, X, Wang, J & Zhu, Y (2016). Structural evolutions and crystal field characterizations of Tm-doped YAlO3: New theoretical insights. ACS Appl Mater Interfaces 8(44), 3042230429.Google Scholar
Jung, HC, Park, JY, Raju, GSR, Jeong, JH, Moon, BK, Kim, JH & Choi, HY (2009). Crystalline structure dependence of luminescent properties of Eu3+-activated Y2O3–Al2O3 system phosphors. Curr Appl Phys 9(3), S217S221.Google Scholar
Kubrin, R (2014). Nanophosphor coatings: Technology and applications, opportunities and challenges. KONA Powder and Particle Journal 31, 2252.Google Scholar
Li, X, Zhang, Y, Geng, D, Lian, J, Zhang, G, Hou, Z & Lin, J (2014). Cagdalo4: Tb3+/Eu3+ as promising phosphors for full-color field emission displays. J Mater Chem C 2(46), 99249933.Google Scholar
Li, K, Zhang, Y, Li, X, Shang, M, Lian, H & Lin, J (2015). Host-sensitized luminescence in LaNbO4:Ln3+(Ln3+=Eu3+/Tb3+/Dy3+) with different emission colors. Phys Chem Chem Phys 17(6), 42834292.Google Scholar
Liu, L, Zhang, Z, Zhang, L & Zhai, Y (2009). The effectiveness of strong afterglow phosphor powder in the detection of fingermarks. Forensic Sci Int 183(1–3), 4549.Google Scholar
Liu, J, Shi, Z, Yu, Y, Yang, R & Zuo, S (2010). Water-soluble multicolored fluorescent CdTe quantum dots: Synthesis and application for fingerprint developing. J Colloid Interface Sci 342(2), 278282.Google Scholar
Loitongbam, RS, Singh, NS, Singh, WR & Ningthoujam, RS (2013). Observation of exceptional strong emission transitions 5Dj (j= 1− 3) to 7Fj (j= 1− 3): Multicolor from single Eu3+ ion doped La2O3 nanoparticles. J Lumin 134, 1423.Google Scholar
Meza-Rocha, AN, Speghini, A, Franchini, J, Lozada-Morales, R & Caldiño, U (2017). Multicolor emission in lithium-aluminum-zinc phosphate glasses activated with Dy3+, Eu3+ and Dy3+/Eu3+. J Mater Sci: Mater Electron 28(14), 1056410572.Google Scholar
Ningthoujam, RS, Gajbhiye, NS, Ahmed, A, Umre, SS & Sharma, SJ (2008). Re-dispersible Li+ and Eu3+ Co-doped nanocrystalline ZnO: Luminescence and EPR studies. J Nanosci Nanotechnol 8(6), 30593062.Google Scholar
Nitta, A, Takase, M, Takashima, M, Murakami, N & Ohtani, B (2016). A fingerprint of metal-oxide powders: Energy-resolved distribution of electron traps. Chem Commun 52(81), 1209612099.Google Scholar
Padhye, P, Alam, A, Ghorai, S, Chattopadhyay, S & Poddar, P (2015). Doxorubicin-conjugated β-NaYF 4: Gd3+/Tb3+ multifunctional, phosphor nanorods: A multi-modal, luminescent, magnetic probe for simultaneous optical and magnetic resonance imaging and an excellent pH-triggered anti-cancer drug delivery nanovehicle. Nanoscale 7(46), 1950119518.Google Scholar
Panigrahi, K, Saha, S, Sain, S, Chatterjee, R, Das, A, Ghorai, UK, Das, NS & Chattopadhyay, KK (2018). White light emitting MgAl2O4: Dy3+, Eu3+ nanophosphor for multifunctional applications. Dalton Trans 47, 12228122242.Google Scholar
Pavasaryte, L, Katelnikovas, A, Klimavicius, V, Balevicius, V, Krajnc, A, Mali, G & Kareiva, A (2017). Eu3+-doped Y3−xNdxAl3O12 garnet: Synthesis and structural investigation. Phys Chem Chem Phys 19(5), 37293737.Google Scholar
Rao, BV, Rambabu, U & Buddhudu, S (2006). Photoluminescence spectral analysis of Eu3+: Phosphors. Phys B 382(1–2), 8691.Google Scholar
Saha, S, Das, S, Ghorai, UK, Mazumder, N, Gupta, BK & Chattopadhyay, KK (2013). Charge compensation assisted enhanced photoluminescence derived from Li-codoped MgAl2O4:Eu3+ nanophosphors for solid state lighting applications. Dalton Trans 42(36), 1296512974.Google Scholar
Saha, S, Das, S, Ghorai, UK, Mazumder, N, Ganguly, D & Chattopadhyay, KK (2015). Controlling nonradiative transition centers in Eu3+ activated CaSnO3 nanophosphors through Na+ co-doping: Realization of ultrabright red emission along with higher thermal stability. J Phys Chem C 119(29), 1682416835.Google Scholar
Saraf, M, Kumar, P, Kedawat, G, Dwivedi, J, Vithayathil, SA, Jaiswal, N & Gupta, BK (2015). Probing highly luminescent europium-doped lanthanum orthophosphate nanorods for strategic applications. Inorg Chem 54(6), 26162625.Google Scholar
Shang, M, Li, C & Lin, J (2014). How to produce white light in a single-phase host?. Chem Soc Rev 43(5), 13721386.Google Scholar
Singh, LR & Ningthoujam, RS (2010). Critical view on energy transfer, site symmetry, improvement in luminescence of Eu3+, Dy3+ doped YVO4 by core-shell formation. J Appl Phys 107(10), 104304.Google Scholar
Som, S & Sharma, SK (2012). Eu3+/Tb3+-codoped Y2O3 nanophosphors: Rietveld refinement, bandgap and photoluminescence optimization. J Phys D: Appl Phys 45(41), 415102415113.Google Scholar
Tian, B, Chen, B, Tian, Y, Li, X, Zhang, J, Sun, J & Wang, Y (2013). Excitation pathway and temperature dependent luminescence in color tunable Ba5Gd8Zn4O21: Eu3+ phosphors. J Mater Chem C 1(12), 23382344.Google Scholar
Van Hest, JJ, Blab, GA, Gerritsen, HC, de Mello Donega, C & Meijerink, A (2017). Probing the influence of disorder on lanthanide luminescence using Eu-doped LaPO4 nanoparticles. J Phys Chem C 121(35), 1937319382.Google Scholar
Wu, YF, Nien, YT, Wang, YJ & Chen, IG (2012). Enhancement of photoluminescence and color purity of CaTiO3: Eu phosphor by Li doping. J Am Ceram Soc 95(4), 13601366.Google Scholar
Xia, G, Zhou, S, Zhang, J, Wang, S, Wang, H & Xu, J (2005). Sol–gel combustion synthesis and luminescence of Y4Al2O9:Eu3 nanocrystal. J Non-Cryst Solids 351(37–39), 29792982.Google Scholar
Zhang, J, Xie, B, Yu, X, Luo, X, Zhang, T, Liu, S & Jin, X (2017). Blue light hazard performance comparison of phosphor-converted LED sources with red quantum dots and red phosphor. J Appl Phys 122(4), 043103.Google Scholar
Zhou, Y, Xiang, H, Lu, X, Feng, Z & Li, Z (2015). Theoretical prediction on mechanical and thermal properties of a promising thermal barrier material: Y4Al2O9. J Adv Ceramics 4(2), 8393.Google Scholar