[1] VERMA S, VERMA K, KUMAR D, et al. Recent advances in rare earth doped alkali-alkaline earth borates for solid state lighting applications[J]. Physica B: condensed matter, 2018, 535:106-113.
[2] TRIPATHI S, TIWARI R, SHRIVASTAVAA K, et al. A review reports on rare earth activated AZrO3 (A = Ba, Ca, Sr) phosphors for display and sensing applications[J]. Optik, 2018, 157:365-381.
[3] GUPTA I, SINGH S, BHAGWAN S, et al. Rare earth (RE) doped phosphors and their emerging applications: a review[J]. Ceramics international, 2021, 47(14): 19282-19303.
[4] LI Y, WANG R, ZHENG W, et al. Silica-coated Ga(III)-doped ZnO:Yb3+, Tm3+ upconversion nanoparticals for high-resolution in vivo bioimaging using near-infrared to near-infrared upconversion emission[J]. Inorganic chemistry, 2019, 58(12):8230-8236.
[5] WANG R, NI S, LIU G, et al. Hollow CaTiO3 cubes modified by La/Cr co-doping for efficient photocatalytic hydrogen production[J]. Applied catalysis B: environmental, 2018, 225:139-147.
[6] WU Y B, ZHAO F Y, PIAO X Q, et al. Zn-doped CaTiO3:Eu3+ red phosphors for enhanced photoluminescence in white LEDs by solid-state reaction[J]. Luminescence, 2016, 31(1):152-157.
[7] JAIN N, SINGHR K, SINGHB P, et al. Enhanced temperature-sensing behavior of Ho3+-Yb3+-codoped CaTiO3 and its hybrid formation with Fe3O4 nanoparticles for hyperthermia[J]. ACS Omega, 2019, 4(4):7482-7491.
[8] LI X, ZHANG Q, AHMAD Z, et al. Near-infrared luminescent CaTiO3:Nd3+ nanofibers with tunable and trackable drug release kinetics[J]. Journal of materials chemistry B, 2015, 37:7449-7456.
[9] TANG P, TOWNER D J, MEIER A L, et al. Low-voltage, polarization-insensitive, electro-optic modulator based on a polydomain barium titanate thin film[J]. Applied physics letters, 2004, 85(20):4615-4617.
[10] FASASIA Y, MAAZA M, ROHWERE G, et al. Effect of Zn-doping on the structural and optical properties of BaTiO3 thin films grown by pulsed laser deposition[J]. Thin solid films, 2008, 516(18):6226-6232.
[11] MENG L, ZHANG K F, PAN K, et al. Controlled synthesis of CaTiO3:Ln3+ nanocrystals for luminescence and photocatalytic hydrogen production[J]. RSC advances, 2016, 6(7):5761-5766.
[12] LI X, LI Y Y, CHEN X Y, et al. Optically monitoring mineralization and demineralization on photoluminescent bioactive nanofibers[J]. Langmuir, 2016, 32(13): 3226-3233.
[13] SPALDINN A, FIEBIG M. The renaissance of magnetoelectric multiferroics[J]. Science, 2005, 309(5733): 391-392.
[14] JIANG Z, PAN J, WANG B, et al. Two dimensional Z-scheme AgCl/Ag/CaTiO3 nano-heterojunctions for photocatalytic hydrogen production enhancement[J]. Applied surface science, 2018, 436:519-526.
[15] OLIVEIRAL H, RAMIREZM A, PONCEM A, et al. Optical and gas-sensing properties, and electronic structure of the mixed-phase CaCu3Ti4O12/CaTiO3 composites[ J]. Materials research bulletin, 2017, 93:47-55.
[16] LI X, LI Y, CHEN X, et al. Optically monitoring mineralization and demineralization on photoluminescent bioactive nano-fibers[J]. Langmuir, 2016, 32(13): 3226-3233.
[17] YAN Y X, YAN G H, ZHAO X X, et al. Enhanced photocatalytic activity of surface disorder-engineered CaTiO3[J]. Materials research bulletin, 2018, 105:286-290.
[18] MAHATA M K, KOPPE T, MONDAL T, et al. Incorporation of Zn2+ ions into BaTiO3:Er3+/Yb3+ nanophosphor :an effective way to enhance upconversion, defect luminescence and temperature sensing[J]. Physical chemistry chemical physics, 2015, 17(32):20741-20753.
[19] WANG Y L, ZHANG W T, ZHANG P C, et al. Effect of replacement of Ca by Zn on the structure and optical property of CaTiO3:Eu3+ red phosphor prepared by sol-gel method[J]. Luminescence, 2015, 30(5):533-537.
[20] YANG X, WILLIAMSI D, CHEN J, et al. Perovskite hollow cubes:morphological control, three-dimensional twinning and intensely enhanced photoluminescence[J]. Journal of materials chemistry, 2008, 18(30): 3543-3546.
[21] YANG X, FU J, JIN C, et al. Formation mechanism of CaTiO3 hollow crystals with different microstructures[J]. Journal of the American chemical society, 2010, 132(40):14279-14287.
