[1] Q SUN, S WANG, B DEVAKUMAR et al. Double perovskite Ca2LuTaO6:Eu3+ red-emitting phosphors: synthesis, structure and photoluminescence characteristics. Journal of Alloys and Compounds, 804, 230-236(2019).

[2] Dongbao LIANG, Rui ZHANG, Yufang SHEN et al. Synthesis and luminescent properties of BaLaGa3O7:Bi3+ phosphors. Acta Photonica Sinica, 51, 0316002(2022).

[3] A FU, A GUAN, F GAO et al. A novel double perovskite La2ZnTiO6:Eu3+ red phosphor for solid-state lighting: Synthesis and optimum luminescence. Optics & Laser Technology, 96, 43-49(2017).

[4] Wang ZHAO, Weiwei ZHOU, Shuhe LIU et al. Luminescent characters and energy transfer mechanisms of BaGd2 (MoO4)4:Tb3+, Eu3+ Phosphors. Chinese Journal of Luminescence, 40, 581-588(2019).

[5] L HUANG, Y LIU, J YU et al. Highly stable K2SiF6:Mn4+@ K2SiF6 composite phosphor with narrow red emission for white leds. ACS applied materials & interfaces, 10, 18082-18092(2018).

[6] X DING, Y WANG. Commendable Eu2+-doped oxide-matrix-based LiBa12 (BO3)7F4 red broad emission phosphor excited by NUV light: electronic and crystal structures, luminescence properties. ACS Applied Materials & Interfaces, 9, 23983-23994(2017).

[7] L HUANG, Y LIU, S SI et al. A new reductive DL-mandelic acid loading approach for moisture-stable Mn4+ doped fluorides. Chemical Communications, 54, 11857-11860(2018).

[8] Y ZHU, S YUAN, L HUANG et al. Optimizing and adjusting the photoluminescence of Mn4+-doped fluoride phosphors via forming composite particles. Dalton Transactions, 48, 711-717(2019).

[9] Cong ZHAO, Qingyu MENG, Wenjun SUN. Luminescence properties of Eu3+ doped CaMoO4 micron phosphors. Acta Physica Sinica, 10, 287-295(2015).

[10] Fei WANG. Preparation and luminescent properties of phosphor Sr2La8(SiO4)6O2:Eu(2+,3+). Acta Photonica Sinica, 47, 0816001(2018).

[11] A K SREELEKSHMI, S C LAL, S GANESANPOTTI. Probing the multifunctionality of double layered perovskite NaGdMgTeO6:Eu3+ in ratiometric phosphor thermometry and solid-state lighting. Journal of Alloys and Compounds, 905, 164138(2022).

[12] B H TOBY, R B VON DREELE. GSAS-II: the genesis of a modern open-source all purpose crystallography software package. Journal of Applied Crystallography, 46, 544-549(2013).

[13] J TAUC, R GRIGOROVICI, A VANCU. Optical properties and electronic structure of amorphous germanium. Physica Status Solidi (b), 15, 627-637(1966).

[14] N J SURAJA, A MAHESH, K S SIBI et al. Insights into the crystal structure and multifunctional optical properties of A2CdTeO6 (A=Ba, Sr, Ca) double perovskites. Journal of Alloys and Compounds, 865, 158902(2021).

[15] Ying YE, Linxiang WANG, TUO Juan et al. Preparation and luminescence properties of metal ions Li+, Na+ and Al3+ co-doped BaF2:Eu3+ phosphors. Acta Photonica Sinica, 47, 0616003(2018).

[16] C CAO, H K YANG, B K MOON et al. Hydrothermal synthesis, phase evolution, and optical properties of Eu3+-doped KF-YF3 system materials. Journal of Materials Research, 27, 2988-2995(2012).

[17] R YU, C WANG, J CHEN et al. Photoluminescence characteristics of Eu3+-doped double-perovskite phosphors. ECS Journal of Solid State Science and Technology, 3, 33-37(2014).

[18] M SEKULIĆ, T DRAMIĆANIN, A ĆIRIĆ et al. Photoluminescence of the Eu3+-activated YxLu1-xNbO4 (x = 0, 0.25, 0.5, 0.75, 1) solid-solution phosphors. Crystals, 12, 427(2022).

[19] Q LIU, L WANG, W HUANG et al. Thermally stable double perovskite CaLaMgSbO6:Eu3+ phosphors as a tunable led-phosphor material. Ceramics International, 44, 1662-1667(2018).

[20] K LI, H LIAN, R VAN DEUN et al. A far-red-emitting NaMgLaTeO6:Mn4+ phosphor with perovskite structure for indoor plant growth. Dyes and Pigments, 162, 214-221(2019).

[21] X ZHANG, L ZHOU, Q PANG et al. Tunable luminescence and Ce3+→Tb3+→Eu3+ energy transfer of broadband-excited and narrow line red emitting Y2SiO5: Ce3+, Tb3+, Eu3+ phosphor. The Journal of Physical Chemistry C, 118, 7591-7598(2014).

[22] Y CHANG, C LIANG, S YAN et al. Synthesis and photoluminescence characteristics of high color purity and brightness Li3Ba2Gd3 (MoO4)8: Eu3+ red phosphors. The Journal of Physical Chemistry C, 114, 3645-3652(2010).

[23] J HE, Z GAO, S LIU et al. New Eu3+-activated bismuthate tellurate LiSrBiTeO6 red-emitting phosphor for InGaN-based w-LEDs. Journal of Luminescence, 202, 7-12(2018).

[24] J LIANG, S ZHAO, X YUAN et al. A novel double perovskite tellurate Eu3+-doped Sr2MgTeO6 red-emitting phosphor with high thermal stability. Optics & Laser Technology, 101, 451-456(2018).

[25] L LI, W CHANG, W CHEN et al. Double perovskite LiLaMgWO6:Eu3+ novel red-emitting phosphors for solid sate lighting: synthesis, structure and photoluminescent properties. Ceramics International, 43, 2720-2729(2017).

[26] Wei LIU, Zhuxin LI, Junjie WANG et al. Regulation of electroluminescent properties of ZnO/GaN light emitting diodes by Er3+ doping. Chinese Journal of Luminescence, 42, 863-870(2021).

[27] M FERHI, C BOUZIDI, K HORCHANI-NAIFER et al. Judd-ofelt analysis of spectroscopic properties of Eu3+ doped KLa(PO3)4. Journal of Luminescence, 157, 21-27(2015).

[28] J ZHONG, H GAO, Y YUAN et al. Eu3+-doped double perovskite-based phosphor-in-glass color converter for high-power warm w-LEDs. Journal of Alloys and Compounds, 735, 2303-2310(2018).

[29] X LI, Q LIU, W HUANG et al. Structural and luminescent properties of Eu3+-doped double perovskite BaLaMgNbO6 phosphor. Ceramics International, 44, 1909-1915(2018).

[30] P DU, J YU. Eu3+-activated La2MoO6-La2WO6 red-emitting phosphors with ultrabroad excitation band for white light-emitting diodes. Scientific Reports, 7, 11953(2017).

[31] T RAGHU, D RAJU, C RATNAKA. Photoluminescence investigations of Eu3+-doped LiPbB5O9 as a red emitting phosphor for warm w-LED applications. Indian Journal of Physics, 96, 1547-1558(2021).

[32] P DU, W RAN, W LI et al. Morphology evolution of Eu3+-activated NaTbF4 nanorods: a highly-efficient near-ultraviolet light-triggered red-emitting platform towards application in white light-emitting diodes. Journal of Materials Chemistry C, 7, 10802-10809(2019).