① Effect of concentration of Ce3+ and Sm3+ on luminescence performance of YLuAG phosphors. Materials Research Express,(2019),6(11).
② Preparation and characterization of YAG: Ce3+ phosphors by molten salt synthesis method. Materials Research Express, (2019) 6:086321.
③ Properties optimization of Er3+ doped lead–sodium–yttrium–fluoride phosphor through combining LCS–HSR method. Journal of Materials Science: Materials in Electronics, (2018)29(12):10016-10025.
④ Effect of the ratio of Er3+ to Y3+ on up-conversion emission properties of BaxNayYzF2x+ y+3z+3m:Er3+m under 1550 nm excitation. Applied Physics A-Materials Science & Processing (2018) 124(2):94-102.
⑤ Er3+,Y3+掺杂浓度对BaxNayYzF2x+y+3z+3m:Er3+m材料上转换发光性能的影响,中国激光, 2017, 44 (10): 1003004-1 ~ 1003004-7.
⑥ Performance optimization of Er3+ doped barium–natrium–yttrium–fluoride phosphor synthesized by the low-temperature combustion synthesis method. J Mater Sci: Mater Electron (2017) 28:10139-10147.
⑦ Preparation of Gd2O2S:Er3+,Yb3+ phosphor and its multi-wavelength sensitive upconversion luminescence mechanism. CrystEngComm, 2015, 17, 1881-1889.
⑧ Optimization of the low temperature combustion synthesis of Er3+ doped lead-natrium-yttrium-fluoride phosphor. Functional Materials Letters, 2014, 7, 1: 1450004.
⑨ Infrared-to-visible upconversion luminescence of Er3+ doped barium-natrium-yttrium-fluoride phosphor. Journal of Luminescence, 131 (2011) 2372-2376.
⑩ Optimization of the synthesis of Er-Y-Ba-Na quaternary fluoride upconversion phosphor and luminescence properties. Advanced Materials Research, 295-297(2011)865-868.