深圳市二维材料孔雀团队
团队成员|宋宇锋研究员——追梦二维材料光学

        宋宇锋,毕业于新加坡南洋理工大学,2014年底进入深圳大学微纳光电子学研究院博士后流动站工作,成为张晗教授课题组成员。在站期间,主要开展从事基于二维材料的超快激光与全光通信器件相关研究。

郭志男
宋宇锋博士在2019LDMO上演讲

  宋宇锋博士主要从事基于二维材料非线性光学特性的超短脉冲光纤激光器及全光通信器件应用两方面的研究。超快激光方面,利用二维材料高效液相剥离方法,以光纤激光器为载体,系统研究基于二维材料被动锁模超短脉冲在光纤激光器中的产生机制及孤子脉冲动力学;全光器件方面,利用高效二维材料制备方法,以微纳光纤为载体,制备基于二维材料-微纳光纤复合机构的非线性光学器件,应用于全光开关,全光波长转换等领域,为二维材料应用于全光通信提供有效的解决方案。


      2019年,宋博士在《Applied Physics Review》上在线发表了题为Recent progress of study on optical solitons in fiber lasers的综述论文,论文系统回顾了光纤激光器中经过实验观察过的光孤子,同时对基于光纤激光器的光孤子研究未来发展做出了展望。宋宇博士近五年发表SCI论文总数超过40一区TOP期刊论文15篇以上。入选ESI高被引论文2篇,热点论文1, H-index20i10-index 25. 主持国家自然科学基金青年基金项目1项。;入选深圳市孔雀计划C类人才;入选南山区领航人才。

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​​​​​​​  科研寄语

 Art is long, life is short  人生有限,学海无涯
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​​​​​​​  个人经历

【本科】2004-2008年,天津大学  精密仪器与光电子工程学院 电子科学与技术(光电子)专业 

【硕博】2008-2013年,新加坡南洋理工大学  电机与电子工程学院

【博后】2013-2015年,新加坡南洋理工大学  电机与电子工程学院

             2015-2017年,深圳大学   光学工程流动站

【工作】2017年-至今 ,深圳大学   二维材料光电科技国际合作联合实验室 副研究员

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​​​​​​​  参与项目

1. 国家自然科学基金青年科学基金项目
基于化学修饰的高稳定黑磷可饱和吸收体的中红外锁模光纤激光器研究2018/01-2020/12,23在研主持


2. 国家自然科学基金面上项目
类黑磷二维材料非线性及超快光学研究2017/01-2017/1216万元,结题,参与
基于二维黑磷/金属纳米复合材料的中红外光探测器研究2019/01-2022/1269万元,在研,参加

3. 国家自然科学基金国际(地区)合作与交流项目

“半导体和光纤激光器中的多种光频率梳产生研究”,2019/01-2021/12200万元,在研,子课题负责人


4. 深圳市科技计划基础面上项目

基于类人算法的智能全光调制器件”, 2020/01-2022/1230万元,在研,主持


5. 深圳大学-台北科技大学2019年度科研合作项目

基于黑磷材料的智能锁模光纤激光器研究”,2020/04-2021/046万元,在研,主持

“基于二维材料的大能量孤子脉冲光纤激光器研究”,2019/04-2020/046万元,在研,参与


6. 横向课题
“基于新型二维材料的锁模激光器中试”,2017/09-2019/09120万元,在研,参与

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​​​​​​​  论文情况

主要发表期刊:

1.          Y. F. Song, J. Guo, L. M. Zhao, D. Y. Shen, and D. Y. Tang, “280 GHz dark soliton fiber laser,” Opt. Lett. 39(22), 3484-3487 (2014). (JCR二区, Q1, IF: 3.866) (18 cites)

被杂志Nature photonics亮点 (M. Maragkou, “A dark soliton laser,” Nat. Photon. 8, 675(2014).)

被中国激光杂志社评为2014中国光学重要成果”.


2.      Y. Song, X. Shi, C. Wu, D. Tang, and H. Zhang, "Recent progress of study on optical solitons in fiber lasers," Appl. Phys. Rev. 6, 021313 (2019). JCR一区, IF: 12.75)


3.      Y. F. Song, Z. M. Liang, X. T. Jiang, Y. X. Chen, Z. J. Li, L. Lu, Y. Q. Ge, K. Wang, J. L. Zheng, S. B. Lu, J. H. Ji, and H. Zhang, "Few-layer antimonene decorated microfiber: ultra-short pulse generation and all-optical thresholding with enhanced long term stability," 2D Mater 4(2017). (JCR一区, Q1, IF: 7.343) (48 cites) (IOP中国高被引论文)


4.      Y. F. Song, H. Zhang, D. Y. Tang, and D. Y. Shen, “Polarization rotation vector solitons in a graphene mode-locked fiber laser,” Optics Express, 20(24), 27283-27289 (2012). (JCR二区, Q1, IF: 3.561) (42 cites)


5.      Y. F. Song, Y. X. Chen, X. T. Jiang, W. Y. Liang, K. Wang, Z. M. Liang, Y. Q. Ge, F. Zhang, L. M. Wu, J. L. Zheng, J. H. Ji, and H. Zhang, "Nonlinear Few-Layer Antimonene-Based All-Optical Signal Processing: Ultrafast Optical Switching and High-Speed Wavelength Conversion," Adv Opt Mater 6(2018). (JCR一区, IF: 7.125) (12 cites)


6.      Y. F. Song, S. Chen, Q. Zhang, L. Li, L. M. Zhao, H. Zhang, and D. Y. Tang, "Vector soliton fiber laser passively mode locked by few layer black phosphorus-based optical saturable absorber," Opt Express 24, 25933-25942 (2016). (JCR二区, Q1, IF: 3.561) (37 cites)


7.      Y. F. Song, L. Li, H. Zhang, D. Y. Shen, D. Y. Tang, and K. P. Loh, "Vector multi-soliton operation and interaction in a graphene mode-locked fiber laser," Opt Express 21, 10010-10018 (2013). (JCR二区, Q1, IF: 3.561) (91 cites)


8.      Y. F. Song, H. Zhang, L. M. Zhao, D. Y. Shen, and D. Y. Tang, "Coexistence and interaction of vector and bound vector solitons in a dispersion-managed fiber laser mode locked by graphene," Opt Express 24, 1814-1822 (2016). (JCR二区, Q1, IF: 3.561) (24 cites)


9.      Y. F. Song, L. Li, D. Y. Tang, and D. Y. Shen, "Quasi-periodicity of vector solitons in a graphene mode-locked fiber laser," Laser Phys Lett 10, 125103 (2013). (JCR三区, Q2, IF: 2.328) (16 cites)


10.  Y. F. Song, Z. M. Liang, H. Zhang, Q. Zhang, L. M. Zhao, D. Y. Shen, and D. Y. Tang, "Period-doubling and quadrupling bifurcation of vector soliton bunches in a graphene mode locked fiber laser," IEEE Photonics J 9(5),1-8 (2017). (JCR三区, Q1, IF: 2.729 (3 cites)


11.  Y. Song, K. You, Y. Chen, J. Zhao, X. Jiang, Y. Ge, Y. Wang, J. Zheng, C. Xing, and H. Zhang, "Lead monoxide: a promising two-dimensional layered material for applications in nonlinear photonics in the infrared band," Nanoscale 11,12595-12602 (2019). (JCR一区, IF: 6.97) (最新发表)


12.  Y.F. Song, Y.X. Chen, X.T. Jiang, Y.Q. Ge, Y.Z. Wang, K.X. You, K. Wang, J.L. Zheng, J.H. Ji, Y.P. Zhang, J.Q. Li, H. Zhang, Nonlinear Few-Layer MXene-Assisted All-Optical Wavelength Conversion at Telecommunication Band, Adv Opt Mater, 7 (2019). (JCR一区, IF: 7.125) (最新发表)


13.   K. Wang, J. Zheng, H. Huang, Y. Chen, Y. Song, J. Ji, and H. Zhang, "All-optical signal processing in few-layer bismuthene coated microfiber: towards applications in optical fiber systems," Opt Express 27, 16798-16811 (2019). (通讯作者)


14.   K. Wang, Y.X. Chen, J.L. Zheng, Y.Q. Ge, J.H. Ji, Y.F. Song, H. Zhang, Black phosphorus quantum dot based all-optical signal processing: ultrafast optical switching and wavelength converting, Nanotechnology, 30 (2019). (通讯作者)


15.  L. J. Li, H. T. Zhang, J. P. Qin, Y. L. Wang, S. S. Li, Y. J. Shen, Z. W. Lv, Y. F. Song, Y. Q. Yang, W. L. Yang, X. M. Duan, and M. H. Chen, "Passive Q-switched operation of an a-cut Tm, Ho:YAP laser with a few-layer WS2 saturable absorber," Laser Phys Lett 15(2018).(共同通讯作者)


16.  L. Lu, Z. M. Liang, L. M. Wu, Y. X. Chen, Y. F. Song, S. C. Dhanabalan, J. S. Ponraj, B. Q. Dong, Y. J. Xiang, F. Xing, D. Y. Fan, and H. Zhang, "Few-layer Bismuthene: Sonochemical Exfoliation, Nonlinear Optics and Applications for Ultrafast Photonics with Enhanced Stability," Laser Photonics Rev 12(2018).(高被引论文,引用108)


17.  Y.Z. Wang, W.C. Huang, C. Wang, J. Guo, F. Zhang, Y.F. Song, Y.Q. Ge, L.M. Wu, J. Liu, J.Q. Li, H. Zhang, An All-Optical, Actively Q-Switched Fiber Laser by an Antimonene-Based Optical Modulator, Laser Photonics Rev, 13 (2019).


18.  C. Wang, Y.Z. Wang, X.T. Jiang, Y.F. Song, F. Zhang, J. Liu, H. Zhang, Thermal stress-induced all-optical modulation in MXene-coated polarization maintaining fiber, Laser Phys Lett, 16 (2019).


19.  G.D. Shao, X. Hu, J. Guo, Y.F. Song, L.M. Zhao, D.Y. Shen, D.Y. Tang, Cavity-assisted modulation instability lasing of a fiber ring laser, Appl Phys B-Lasers O, 125 (2019).


20.  G.D. Shao, J. Guo, X. Hu, Y.F. Song, L.M. Zhao, D.Y. Tang, Vector dark solitons in a single mode fibre laser, Laser Phys Lett, 16 (2019).


21.  J. Ma, G.D. Shao, Y.F. Song, L.M. Zhao, Y.J. Xiang, D.Y. Shen, M. Richardson, D.Y. Tang, Observation of dark-bright vector solitons in fiber lasers, Opt Lett, 44 (2019) 2185-2188.


22.  J.F. Liu, X.Z. Li, Y.J. Xu, Y.Q. Ge, Y.Z. Wang, F. Zhang, Y.W. Wang, Y.Y. Fang, F.M. Yang, C. Wang, Y.F. Song, S.X. Xu, D.Y. Fan, H. Zhang, NiPS3 nanoflakes: a nonlinear optical material for ultrafast photonics, Nanoscale, 11 (2019) 14383-14391.


23.  X. Hu, J. Guo, G.D. Shao, Y.F. Song, S.W. Yoo, B.A. Malomed, D.Y. Tang, Observation of incoherently coupled dark-bright vector solitons in single-mode fibers, Opt Express, 27 (2019) 18311-18317.


24.  P. Guo, X. Li, T. Chai, T. Feng, Y. Ge, Y. Song, Y. Wang, Few-layer bismuthene for robust ultrafast photonics in C-Band optical communications, Nanotechnology, DOI 10.1088/1361-6528/ab2150(2019).


25.  J. Guo, J. Zhao, D. Huang, Y. Wang, F. Zhang, Y. Ge, Y. Song, C. Xing, D. Fan, H. Zhang, Two-dimensional tellurium-polymer membrane for ultrafast photonics, Nanoscale, 11 (2019) 6235-6242.


26.  J. Guo, D.Z. Huang, Y. Zhang, H.Z. Yao, Y.Z. Wang, F. Zhang, R. Wang, Y.Q. Ge, Y.F. Song, Z.N. Guo, F.M. Yang, J.F. Liu, C.Y. Xing, T.Y. Zhai, D.Y. Fan, H. Zhang, 2D GeP as a Novel Broadband Nonlinear Optical Material for Ultrafast Photonics, Laser Photonics Rev, 13 (2019).


27.  J. Guo, X. Hu, Y.F. Song, G.D. Shao, L.M. Zhao, D.Y. Tang, Observation of vector solitons supported by third-order dispersion, Phys Rev A, 99 (2019).


28.  Y. Ge, W. Huang, F. Yang, J. Liu, C. Wang, Y. Wang, J. Guo, F. Zhang, Y. Song, S. Xu, D. Fan, H. Zhang, Beta-lead oxide quantum dot (beta-PbO QD)/polystyrene (PS) composite films and their applications in ultrafast photonics, Nanoscale, 11 (2019) 6828-6837.


29.  C.Y. Xing, X. Chen, W.C. Huang, Y.F. Song, J.H. Li, S. Chen, Y.H. Zhou, B.Q. Dong, D.Y. Fan, X. Zhu, H. Zhang, Two-Dimensional Lead Monoxide: Facile Liquid Phase Exfoliation, Excellent Photoresponse Performance, and Theoretical Investigation, Acs Photonics, 5 (2018) 5055-5067.


30.  Y.Z. Wang, F. Zhang, X. Tang, X. Chen, Y.X. Chen, W.C. Huang, Z.M. Liang, L.M. Wu, Y.Q. Ge, Y.F. Song, J. Liu, D. Zhang, J.Q. Li, H. Zhang, All-Optical Phosphorene Phase Modulator with Enhanced Stability Under Ambient Conditions, Laser Photonics Rev, 12 (2018).

31.  Y.Q. Ge, Z.F. Zhu, Y.H. Xu, Y.X. Chen, S. Chen, Z.M. Liang, Y.F. Song, Y.S. Zou, H.B. Zeng, S.X. Xu, H. Zhang, D.Y. Fan, Broadband Nonlinear Photoresponse of 2D TiS2 for Ultrashort Pulse Generation and All-Optical Thresholding Devices, Adv Opt Mater, 6 (2018).

32.  Y.Q. Ge, Z.M. Liang, Y.X. Chen, Y.F. Song, L. Li, H. Zhang, L.M. Zhao, D.Y. Fan, Characterization of Dark Soliton Sidebands in All-Normal-Dispersion Fiber Lasers, Ieee J Sel Top Quant, 24 (2018).


33.  T. Chai, X.H. Li, T.C. Feng, P.L. Guo, Y.F. Song, Y.X. Chen, H. Zhang, Few-layer bismuthene for ultrashort pulse generation in a dissipative system based on an evanescent field, Nanoscale, 10 (2018) 17617-17622.


34.  J.L. Zheng, X. Tang, Z.H. Yang, Z.M. Liang, Y.X. Chen, K. Wang, Y.F. Song, Y. Zhang, J.H. Ji, Y. Liu, D.Y. Fan, H. Zhang, Few-Layer Phosphorene-Decorated Microfiber for All-Optical Thresholding and Optical Modulation, Adv Opt Mater, 5 (2017).


35.  Y.Q. Ge, S. Chen, Y.J. Xu, Z.L. He, Z.M. Liang, Y.X. Chen, Y.F. Song, D.Y. Fan, K. Zhang, H. Zhang, Few-layer selenium-doped black phosphorus: synthesis, nonlinear optical properties and ultrafast photonics applications, J Mater Chem C, 5 (2017) 6129-6135.


36.  G.D. Shao, Y.F. Song, L.M. Zhao, D.Y. Shen, D.Y. Tang, Temporal vector cavity solitons in a net anomalous dispersion fiber laser, Laser Phys Lett, 13 (2016).


37.  G.D. Shao, Y.F. Song, L.M. Zhao, D.Y. Shen, D.Y. Tang, Vector Gain-Guided Dissipative Solitons in a Net Normal Dispersive Fiber Laser, Ieee Photonic Tech L, 28 (2016) 975-978.


38.  J. Guo, Y.F. Song, Y.J. Xiang, H. Zhang, D.Y. Tang, Controlled Generation of Bright or Dark Solitons in a Fiber Laser by Intracavity Nonlinear Absorber, Ieee Photonics J, 8 (2016).


39.  G.D. Shao, Y.F. Song, L.M. Zhao, D.Y. Shen, D.Y. Tang, Soliton-dark pulse pair formation in birefringent cavity fiber lasers through cross phase coupling, Opt Express, 23 (2015) 26252-26258.


40.  G.D. Shao, Y.F. Song, J. Guo, L.M. Zhao, D.Y. Shen, D.Y. Tang, Induced dark solitary pulse in an anomalous dispersion cavity fiber laser, Opt Express, 23 (2015) 28430-28437.


41.  D.Y. Tang, J. Guo, Y.F. Song, H. Zhang, L.M. Zhao, D.Y. Shen, Dark soliton fiber lasers, Opt Express, 22 (2014).


42.  D.Y. Tang, J. Guo, Y.F. Song, G.D. Shao, L.M. Zhao, D.Y. Shen, Temporal cavity soliton formation in an anomalous dispersion cavity fiber laser, J Opt Soc Am B, 31 (2014) 3050-3056.


43.  D.Y. Tang, J. Guo, Y.F. Song, L. Li, L.M. Zhao, D.Y. Shen, GHz pulse train generation in fiber lasers by cavity induced modulation instability, Opt Fiber Technol, 20 (2014) 610-614.


44.  D.Y. Tang, Y.F. Song, J. Guo, Y.J. Xiang, D.Y. Shen, Polarization Domain Formation and Domain Dynamics in a Quasi-Isotropic Cavity Fiber Laser, Ieee J Sel Top Quant, 20 (2014).


45.  D.Y. Tang, L. Li, Y.F. Song, L.M. Zhao, H. Zhang, D.Y. Shen, Evidence of dark solitons in all-normal-dispersion-fiber lasers, Phys Rev A, 88 (2013).


46.  Q.N. Nam, Y.F. Song, B. Lin, Design of Hilbert transformers with tunable THz bandwidths using a reconfigurable integrated optical FIR filter, Opt Commun, 284 (2011) 787-794.


47.  Q.N. Nam, Y.F. Song, On the interrelations between an optical differentiator and an optical Hilbert transformer, Opt Lett, 36 (2011) 915-917.


48.  B. Lin, S.C. Tjin, N.Q. Ngo, Y.F. Song, S. Liang, L. Xia, M. Jiang, Analysis of inverse-Gaussian apodized fiber Bragg grating, Appl Optics, 49 (2010) 4715-4722.