[1]Yuneng Ren*, Kai Qin, Yan Chen, Qing Lin, Dongyang Xu, Zhiduo Xin, Jian Ni, Liang Ge. Thermomechanical response of copper films irradiated by femtosecond-pulsed lasers with dynamic optical properties, Applied Optics, 2019, 58, 871-878.
[2]Qing Lin, Naifei Ren*, Yuneng Ren*, Yan Chen, Zhiduo Xin, Yongsheng Fan, Xudong Ren, Lin Li. Theoretical study on femtosecond laser optical breakdown threshold in water mediated by aluminum nanoparticle coated with silica, Optics Express, 2018, 26, 34200-34213.
[3]Ning Xue, Yunpeng Ren*, Xudong Ren, Qing Lin, Qiqi Wang, Kai Qin. Phase field simulation of dendritic growth of copper films irradiated by ultrashort laser pulses. Computational Materials Science, 2018, 148, 60-68.
[4]Qing Lin, Naifei Ren*, Yunpeng Ren*, Qiqi Wang, Ning Xue, Zhiduo Xin, Xudong Ren. Shockwave propagation and pressure in aluminum films induced by hot-electron-blast during femtosecond-pulsed laser irradiation, OPTIK, 2018, 172, 137-143.
[5]Chunxia Lei, Yunpeng Ren*, Yong Gan, Jiajian Lin, Yan Chen. Effect of optical properties on the thermal responses of copper films induced by ultrafast lasers, High Power Laser and Particle Beams, 2017, 29, 071006-1-5.
[6]Qing Lin, Naifei Ren*, Yunpeng Ren*, Qiqi Wang, Ning Xue, Xudong Ren, Lin Li. Dynamic thermal response of aluminum films induced by femtosecond-pulsed lasers with temperature-dependent optical properties, OPTIK, 2017, 142, 218-225.
[7]X. D. Ren, H. He, Y. Q. Tong, Y. P. Ren, S. Q. Yuan, R. Liu, C. Y. Zuo, K. Wu, S. Sui, D. S. Wang, Experimental investigation on dynamic characteristics and strengthening mechanism of laser induced cavitation bubbles, Ultrasonics Sonochemistry, 2016, 32, 218-223.
[8]X. D. Ren, R. Liu, L. M. Zheng, Y. P. Ren, Z. Z. Hu, and H. He, Morphology selective preparation and formation mechanism of graphene nanoribbons from graphite by liquid-phase pulsed laser ablation, Applied Physics Letters, 2016, 108, 071904.
[9]Wangfan Zhou, Xudong Ren, Fanfan Liu, Yunpeng Ren, Lin Li, Nanocrystallization in the Duplex Ti-6Al-4V Alloy Processed by Multiple Laser Shock Peening, Metals, 2016, 6(12), 297-306.
[10]X. D. Ren, W. F. Zhou, Y. P. Ren, S. D. Xu, F. F. Liu, S. Q. Yuan, N. F. Ren, J. J. Huang, Dislocation evolution and properties enhancement of GH2036 by laser shock processing: Dislocation dynamics simulation and experiment, Materials Science & Engineering A, 2016, 654, 184-192.
[11]X. D. Ren, W. F. Zhou, F. F. Liu, Y. P. Ren, S. Q. Yuan, N. F. Ren, S. D. Xu, T. Yang, Microstructure evolution and grain refinement of Ti-6Al-4V alloy by laser shock processing, Applied Surface Science, 2016, 363, 44-49.
[12]X. D. Ren, R. Liu, L. M. Zheng, Y. P. Ren, Z. Z. Hu, H. He, Graphite to ultrafine nanocrystalline diamond phase transition model and growth restriction mechanism induced by nanosecond laser processing, Applied Physics Letters, 2015, 107, 141907.
[13]S. Y. Wang, Y. Ren, K. P. Chang, C. W. Cheng, J. K. Chen, D. Y. Tzou, Ablation of copper by a single ultrashort laser pulse, Journal of Laser Micro/Nanoengineering, 2014, 9(2), 88-92.
[14]C. Zhang, Y. Ren, X. Chen. The development situation of selective laser melting metal powder based on 3D printing, Advanced Materials Research, 2014, 518, 12-18.
[15]Y. Ren, C. W. Cheng, J. K. Chen, Y. Zhang, D. Y. Tzou, Thermal ablation of metal films by femtosecond laser bursts, International Journal of Thermal Science, 2013, 70(8), 32-40.
[16]S. Y. Wang, Y. Ren, C. W. Cheng, J. K. Chen, D. Y. Tzou, Micromachining of copper by femtosecond laser pulses, Applied Surface Science, 2013, 265, 302-308.
[17]Y. Ren, Y. Zhang, J. K. Chen, Z. C. Feng, Inverse estimation of front surface temperature of a 3-D finite slab based on back surface temperature measured at course grids, Numerical Heat Transfer, Part B: Fundamentals, 2013, 63(1), 1-17.
[18]Y. Ren, J. K. Chen, Y. Zhang, Heat transfer in metal films irradiated by combined nanosecond laser pulse and femtosecond pulse train, Frontiers in Heat and Mass Transfer, 2012, 3(2), 023001.
[19]Y. Ren, J. K. Chen, Y. Zhang, Modeling of ultrafast phase changes in metal films induced by an ultrashort laser pulse using a semi-classical two temperature model, International Journal of Heat and Mass Transfer, 2012, 55(5-6), 1620-1627.
[20]Y. Ren, J. K. Chen, Y. Zhang, Optical properties and thermal response of copper films induced by ultrashort-pulsed lasers, Journal of Applied Physics, 2011, 110(11), 113102.
[21] Li-jing Huang*, Bao-jia Li*, Hai-di Cao, Wei Zu, Nai-fei Ren, Hua Ding, Influence of annealing temperature on formation and photoelectric properties of AZO nanosheet-coated FTO-based films, Journal of Materials Science: Materials in Electronics, 2017, 28(6): 4706–4712
[22] Li-jing Huang, Bao-jia Li*, Nai-fei Ren, Enhancing optical and electrical properties of Al-doped ZnO coated polyethylene terephthalate substrates by laser annealing using overlap rate controlling strategy, Ceramics International, 2016, 42(6): 7246–7252
[23] Li-jing Huang, Nai-fei Ren*, Bao-jia Li*, Ming Zhou, Ni/FTO bilayer thin films with high photoelectric properties optimized by magnetic-field-assisted laser annealing, Materials Letters, 2015, 140: 75–78
[24] Li-jing Huang, Nai-fei Ren*, Bao-jia Li, Ming Zhou, A comparative study of different M(M=Al, Ag, Cu)/FTO bilayer composite films irradiated with nanosecond pulsed laser, Journal of Alloys and Compounds, 2014, 617: 915–920
[25] Li-jing Huang, Nai-fei Ren*, Bao-jia Li, Ming Zhou, Improvement in overall photoelectric properties of Ag/FTO bilayer thin films using furnace/laser dual annealing, Materials Letters, 2014, 116: 405–407
[26] Jing Tan, Rui Zou, Jie Zhang, Wang Li, Liqun Zhang and Dongmei Yue*, Large-scale synthesis of N-doped carbon quantum dots and their phosphorescence properties in a polyurethane matrix. Nanoscale, 2016, 8, 4742-4747. (IF = 7.17)
[27] Jing Tan, Zhenzhao Yi, Yunxia Ye, Xudong Ren, Qijun Li*, Achieving red room temperature afterglow carbon dots in composite matrices through chromophore conjugation degree controlling, Journal of Luminescence, 2020, 223, 117267. (IF = 2.9)
[28] Jing Tan*, Xunya Ye, Xudong Ren, Wei Zhao, and Dongmei Yue*, High pH-induced efficient room-temperature phosphorescence from carbon dots in hydrogen-bonded matrices, Journal of Materials Chemistry C, 2018, 6, 7890-7895. (IF = 6.28)
[29] Jing Tan, Jie Zhang, Wang Li, Liqun Zhang and Dongmei Yue*, Synthesis of amphiphilic carbon quantum dots with phosphorescence properties and their multifunctional applications, Journal of Materials Chemistry C, 2016, 4, 10146-10153. (IF = 6.28)
[30] Jie Zhang, Yao Chen, Jing Tan, Haitao Sang, Liqun Zhang and Dongmei Yue*, The synthesis of rhodium/carbon dots nanoparticles and its hydrogenation application. Applied Surface Science, 2017, 396, 1138-1145
[31] Rui Zou, Jing Tan, Kun Liu, Lu Liang, Xingwang Cheng, Xu Zhang, Liqun Zhang and Dongmei Yue*, Hydrogenated hydroxy-terminated butadiene-acrylonitrile copolymer-based polyurethane elastomer with improved mechanical properties and aging resistance. RSC Advances, 2016, 6, 20198-20201
[32] Jingjing Zhang, Kai Guo.Towards realizable design of on-chip optical-driven quantum interferometer at telecom wavelengths [J]. Physical Review Applied, 2018, 10(5), 054029.
[33] Jingjing Zhang, Kai Guo. Design of polarization-insensitive high visibility silicon-on-insulator quantum interferometer [J]. Scientific Reports 2018, 8, (1), 14613.
[34] Jingjing Zhang, Junbo Yang. Ultrashort and efficient adiabatic waveguide taper based on thin flat focusing lenses [J]. Optics Express, 2017, 25 (17) :19894-19903;
[35] Jingjing Zhang, Junbo Yang. Broadband TM-mode-pass polarizer and polarization beam splitter using asymmetrical directional couplers based on silicon subwavelength grating[J]. Optics Communications. 2017,407:46-50;
[36] Jingjing Zhang, Junbo Yang, Huanyu Lu, Wenjun Wu, Jie Huang, Shengli Chang. Subwavelength TE/TM grating coupler based on silicon-on-insulator [J]. Infrared Physics & Technology. 2015,71, 542 – 546;
[37] Jingjing Zhang, Junbo Yang, Huanyu Lu, Wenjun Wu, Jie Huang, Shengli Chang Polarization-independent grating coupler based on silicon-on-insulator[J], Chinese optics letters, 2015, 13(9): 091301:1-5;
[38] Jingjing Zhang, Junbo Yang, Huanyu Lu, Wenjun Wu, Honghui Jia , Shengli Chang. High performance silicon-on-sapphire subwavelength grating coupler for 2.7 wavelength, photonics 2015 – Int’l Conf. on Photonics, Optics and Laser Technology, in Berlin, Germany.
[39] Jingjing Zhang, Dingbo Chen,Junbo Yang Hailiang Zhang, Shengli Chang, Honghui Jia. A high-performance and cost-effective grating coupler for ultraviolet light. Applied Optics and Photonics China).
[40] Jingjing Zhang, Junbo Yang, Huanyu Lu, Wenjun Wu, Honghui Jia, Shengli Chang Vertical coupling and polarization-independent subwavelength grating beam splitter based on silicon-on-insulator [J]. Microwave photonics technology and application conference.
[41] Junbo Yang, Jingjing Zhang, Shuzhi Xu and Shengli Chang,Beam splitter based on Bragg grating-assisted coupler [J], Chinese optics letters, 2015, 13(Suppl.), S12501.
[42] Junbo Yang, Jingjing Zhang, Shuzhi Xu and Shengli Chang. High-performance subwavelength grating coupler based on high-reflectivity grating reflector [J]. Optical Engineering, 2014, 53(9):744-744.