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1. 2011Äê10ÔÂÖÁ½ñ£¬ÖйúÎïÀíѧ»á¸±Àíʳ¤

2. 2016Äê1ÔÂÖÁ½ñ£¬¹ú·À»ù´¡¿ÆÑк˿ÆѧÌôսרÌâ¡°¸ßÄÜÁ¿ÃܶȿÆѧ¡±ÁìÓòÊ×ϯ¿Æѧ¼Ò

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1. Wen-shuai Zhang, Hong-bo Cai, Liu-lei Wei, Jian-min Tian and Shao-ping Zhu, Enhanced ion acceleration in the ultra-intense laser driven magnetized  collisionless shocks, New J. Phys. 21, 043026(2019).

2. ÎºÁôÀÚ£¬²Ìºé²¨£¬ÕÅÎÄ˧£¬ÌｨÃñ£¬ÕŶ÷ºÆ£¬ÐÜ¿¡£¬ ÖìÉÙƽ£¬³¬Ç¿¼¤¹âÓëÅÝĭ΢½á¹¹°ÐÏ໥×÷ÓÃÌá¸ßÇ¿Á÷µç×ÓÊø²ú¶îÄ£ÄâÑо¿£¬ÎïÀíѧ±¨ 68, 094101(2019)¡£

3. B Qiao, X F Shen, H He, Y Xie, H Zhang, C T Zhou, S P Zhu and X T He, Revisit on ion acceleration mechanisms in solid targets driven by intense laser pulses, Plasma Phys. Control. Fusion 61, 014039 (2019) .

4. X. F. Shen, B. Qiao, H. Zhang, Y. Xie, S. Kar, M. Borghesi, M. Zepf, C. T. Zhou, S. P. Zhu and X. T. He, Electrostatic capacitance-type acceleration of ions with an intense few-cycle laser pulse, Appl. Phys. Lett. 114, 144102 (2019).

5. H. He, B. Qiao, X. F. Shen, W. P. Yao, Y. Xie, C. T. Zhou, X. T. He, S. P. Zhu, W.B. Pei and S. Z. Fu, High-flux high-energy ion beam production from stable collisionless shock acceleration by intense petawatt-picosecond laser pulses, New J. Phys. 21,  033035(2019).

6. Weipeng Yao, Bin Qiao, Zhonghai Zhao, Zhu Lei, Hua Zhang, Cangtao Zhou, Shaoping Zhu, and Xiantu He, Kinetic Particle-in-cell Simulations of the Transport of Astrophysical Relativistic Jets in Magnetized Intergalactic Medium, The Astrophysical Journal 876,  (2019).

7. X R Xu, B Qiao, H X Chang, Y X Zhang, H Zhang, C L Zhong, C T Zhou, S P Zhu and X T He, Coherent synchrotron emission in transmission with double foil target, Plasma Phys. Control. Fusion 60, 045005(2018).

8. Y. X. Zhang, B. Qiao, X. R. Xu, H. X. Chang, M. Y. Yu, C. L. Zhong, C. T. Zhou, S. P. Zhu, and X. T. He, Intense single attosecond pulse generation from near-critical-density plasmas irradiated by a few-cycle laser pulse, Physics of Plasmas 25, 023302 (2018).

9. Huasen Zhang, Wei Jiang, Fengjun Ge, Peng Song, Shiyang Zou, Tianxuan Huang, Sanwei Li, Dong Yang, Zhichao Li, Lifei Hou, Liang Guo, Xingsen Che, Huabing Du, Xufei Xie, Xiaoan He, Chaoguang Li, Weiyi Zha, Tao Xu,  Yonggang Liu, Huiyue Wei, Xiangming Liu, Zhongjing Chen, Xing Zhang, Ji Yan, Yudong Pu, Xiaoshi, Peng, Yulong Li, Peijun Gu, Wudi Zheng, Jie Liu, Yongkun Ding, and Shaoping Zhu, Investigation of the cylindrical vacuum hohlraum energy in the first implosion experiment at the SGIII laser facility, Physics of Plasmas 25, 022703 (2018).

10. Wen-shuai Zhang, Hong-bo Cai and Shao-ping Zhu, The formation and dissipation of electrostatic shock waves: the role of ion¨Cion acoustic instabilities, Plasma Phys. Control. Fusion 60, 055001(2018).

11. L. Q. Shan, H. B. Cai, W. S. Zhang, Q. Tang, F. Zhang, Z. F. Song, B. Bi, F. J. Ge, J. B. Chen, D. X. Liu, W.W. Wang, Z. H. Yang, W. Qi, C. Tian, Z. Q. Yuan, B. Zhang, L. Yang, J. L. Jiao, B. Cui, W. M. Zhou, L. F. Cao, C. T. Zhou, Y. Q. Gu, B. H. Zhang, S. P. Zhu and X. T. He, Experimental Evidence of Kinetic Effects in Indirect-Drive Inertial Confinement Fusion Hohlraums, Phys. Rev. Lett. 120, 195001(2018). 

12. Weiwu Wang, Hongbo Cai, Jian Teng, Jia Chen, Shukai He, Lianqiang Shan, Feng Lu, Yuchi Wu, Bo Zhang, Wei Hong, Bi Bi, Feng Zhang, Dongxiao Liu, Feibiao Xue, Boyuan Li, Hongjie Liu, Wu He, Jinlong Jiao, Kegong Dong, Faqiang Zhang, Yingling He, Bo Cui, Na Xie, Zongqiang Yuan, Chao Tian, Xiaodong Wang, Kainan Zhou,  Zhigang Deng, Zhimeng Zhang, Weimin Zhou, Leifeng Cao, Baohan Zhang, Shaoping Zhu, Xiantu He and Yuqiu Gu, Efficient production of strong magnetic fields from ultraintense ultrashort laser pulse with capacitor-coil target, Physics of Plasmas 25, 083111 (2018).

13. X. B. Li£¬B. Qiao, H. X. Chang£¬H. He, W. P. Yao, X. F. Shen, J. Wang, Y. Xie, C. L. Zhong, C. T. Zhou, S. P. Zhu and X. T. He£¬Identifying the quantum radiation reaction by using colliding ultraintense lasers in gases£¬Phys. Rev A, 98, 052119 (2018).

14. Wen-Shuai Zhang, Hong-Bo Cai, Lian-Qiang Shan, Hua-Sen Zhang, Yu-Qiu Gu and Shao-Ping Zhu, Anomalous neutron yield in indirect-drive inertial-confinement-fusion due to the formation of collisionless shocks in the corona, Nucl. Fusion 57, 066012(2017).

15. Z. Xu, , B. Qiao, W. P. Yao,  H. X. Chang, C. T. Zhou, S. P. Zhu and X. T. He, Magnetic X points disturbed by the in-plane electric fields, Physics of Plasmas 24, 092102 (2017).

16. W. P. Yao, B. Qiao, Z. Xu, H. Zhang, H. X. Chang, C. T. Zhou, S. P. Zhu, X. G. Wang and X. T. He,  Relay transport of relativistic flows in extreme magnetic fields of stars, Physics of Plasmas 24, 082904 (2017).

17. Yuxue Zhang, Bin Qiao, Xinrong Xu, Hengxin Chang, Haiyang Lu, Cangtao Zhou, Hua Zhang, Shaoping Zhu, Matthew Zepf  and Xiantu He, Intense attosecond pulses from  laser-irradiated near-critical-density plasmas, Optics Express 25, 29058(2017).

18. ÕÅ»ª¡¢Îâ˼ÖÒ¡¢Öܲ×ÌΡ¢ºÎÃñÇä¡¢²Ìºé²¨¡¢²ÜÀò»ª¡¢ÖìÉÙƽ¡¢ºØÏÍÍÁ£¬Çò×ø±ê¶¯Á¿¿Õ¼äÏÂÏà¶ÔÂÛVlasov·½³ÌµÄÊýÖµËã·¨£¬¼ÆËãÎïÀí 34£¬543£¨2017£©¡£

19. ÕÅ»ª¡¢Îâ˼ÖÒ¡¢Öܲ×ÌΡ¢ºÎÃñÇä¡¢²Ìºé²¨¡¢²ÜÀò»ª¡¢ÖìÉÙƽ¡¢ºØÏÍÍÁ£¬µç×ÓÊøÄÜÁ¿³Á»ýµÄÏà¶ÔÂÛFokker-Planch·½³ÌµÄ¼ÆËã·½·¨£¬¼ÆËãÎïÀí 34£¬555£¨2017£©¡£

20. Y. X. Zhang, B. Qiao, X. R. Xu, H. X. Chang, H. Zhang, H. Y. Lu, M. Y. Yu, C. T.  Zhou, S. P. Zhu, and X. T. He, Attosecond light pulses generation along the target surface driven by obliquely-incident lasers, Phys.Plasmas 24, 123119 (2017).

21. Xin Li, Chang-Shu Wu, Zhen-Sheng Dai, Wu-Di Zheng, Jian-Fa Gu, Pei-Jun Gu), Shi-Yang Zou), Jie Liu, and Shao-Ping Zhu, A new ignition hohlraum design for indirect-drive inertial confinement fusion, Chin. Phys. B 25, 085202(2016).

22. Jianfa Gu, Zhensheng Dai, Peng Song, Shiyang Zou, Wenhua Ye, Wudi Zheng, Peijun Gu, Jianguo Wang, and Shaoping Zhu, Asymmetric-shell ignition capsule design to tune the low-mode asymmetry during the peak drive, Physics of Plasmas 23, 082703 (2016).

23. H. Zhang, D. Yang, P. Song, S. Zou, Y. Zhao, S. Li, Z. Li, L. Guo, F. Wang, W. Zheng, P. Gu, W. Pei, S. Zhu, S. Jiang, and Y. Ding, Investigating the hohlraum radiation properties through the angular distribution of the radiation temperature, Physics of Plasmas 23, 082708 (2016).

24. Min-Qing He, Hong-Bo Cai, Hua Zhang, Quan-Li Dong, Cang-Tao Zhou, Si-Zhong Wu, Zheng-Ming Sheng, Li-Hua Cao, Chun-Yang Zheng, Jun-Feng Wu, Mo Chen, Wen-Bing Pei, Shao-Ping Zhu and X. T. He, A spherical shell target scheme for laser-driven neutron sources, Phys. Plasmas 22 (2015), 123103-1/123103-7.

25. Wen-shuai Zhang, Hong-bo Cai and Shao-ping Zhu, Guiding and focusing of fast electron beams produced by ultra-intense laser pulse using a double cone funnel target, Phys. Plasmas 22 (2015), 103109-1/103109-7.

26. Gu Jian-Fa, Dai Zhen-Sheng, Li Yong-Sheng, Song Peng, Ye Wen-Hua, Zou Shi-Yang, Zheng Wu-Di, Zhu Shao-Ping, Optimization of the Doped Ablator Layers for the Plastic Ignition Capsule, Communications in Theoretical Physics 63 (2014), 236/242.

27. Hong-bo Cai, Si-zhong Wu, Jun-feng Wu, Mo Chen, Hua Zhang, Ming-qing He, Li-hua Cao, Cang-tao Zhou, Shao-ping Zhu, Xian-tu He, Review of the current statue of fast ignition research at the IAPCM, High Power Laser Science and Engineering 2 (2014), 4/12.

28. ²Ìºé²¨£¬Öܲ×ÌΣ¬¼ÖÇ࣬Îâ˼ÖÒ£¬ºÎÃñÇ䣬²ÜÀò»ª£¬³ÂĬ£¬ÕÅ»ª£¬Áõ½Ü£¬ÖìÉÙƽ£¬ºØÏÍÍÁ£¬¼¤¹âÇý¶¯Ç¿Á÷µç×ÓÊø²úÉúºÍ¿ØÖÆ£¬Ç¿¼¤¹âÓëÁ£×ÓÊø27 (2015)£¬032001-1/032001-15¡£

29. ºÂÁÁ£¬ÁõÕ¼¾ü£¬ºúÏþÑ࣬Ïî½­£¬Àî±ó£¬Ö£´ºÑô£¬ÖìÉÙƽ£¬ºÚÇ»µÈÀë×ÓÌåÖÐSRSÓëSBS¹ý³ÌµÄÉ¢Éä¹âÆ×·ÖÎö£¬Ç¿¼¤¹âÓëÁ£×ÓÊø 27 (2015)£¬032004-1/032004-9¡£

30. ¿µ¶´¹ú£¬Ö£Î޵У¬ÍõÃô£¬ÅáÎıø£¬ÖìÉÙƽ£¬¼¤¹â¾Û±ä³å»÷²¨µã»ðµÄÈÈ°ßÐγɻúÖÆ£¬Ç¿¼¤¹âÓëÁ£×ÓÊø 27 (2015)£¬032005-1/032005-7¡£

31. ´÷ÕñÉú£¬Àî¼Íΰ£¬Ö£Î޵У¬ÅáÎıø£¬ÖìÉÙƽ£¬¼ä½ÓÇý¶¯À䶳˫¿Ç²ãµã»ð°ÐµÄÉè¼ÆºÍ·ÖÎö£¬Ç¿¼¤¹âÓëÁ£×ÓÊø 27 (2015)£¬032006-1/032006-7¡£

32. ËÎÅô£¬µÔ´«ÀÚ£¬ÀîË«¹ó£¬ÓÂçñ£¬Æë½ø£¬º¼ÐñµÇ£¬ÑîÈÝ£¬³É¾ê£¬ÔøÇåºì £¬ºúÏþÑà £¬Íõ˧£¬Ê©Ò⣬֣Î޵У¬¹ÅÅà¿¡£¬×ÞÊ¿Ñô£¬ÀîÐÀ£¬ÕÔÒæÇ壬ÕÅèëÉ­£¬ÕÅ°®Ç壬°²ºã±ó£¬Àî¾´ºê£¬ÅáÎıø£¬ÖìÉÙƽ£¬¼¤¹â¼ä½ÓÇý¶¯¹ßÐÔÔ¼Êø¾Û±ä¶þά×ÜÌå³ÌÐò--LARED¼¯³É³ÌÐò£¬Ç¿¼¤¹âÓëÁ£×ÓÊø 27 (2015)£¬032007-1/032007-7¡£

33. Îâ˼ÖÒ£¬ÕÅ»ª£¬Öܲ×ÌΣ¬Îâ¿¡·å£¬²Ìºé²¨£¬²ÜÀò»ª£¬ºÎÃñÇ䣬ÖìÉÙƽ£¬ºØÏÍÍÁ£¬¿ìµã»ðÖÐÏà¶ÔÂÛµç×ÓÊøÄÜÁ¿³Á»ýµÄ¶¯ÀíѧÑо¿£¬Ç¿¼¤¹âÓëÁ£×ÓÊø 27 (2015)£¬032010-1/032010-10¡£

34. Jianfa Gu, Zhensheng Dai, Zhengfeng Fan, Shiyang Zou, Wenhua Ye, Wenbing Pei, and Shaoping Zhu, A new metric of the low-mode asymmetry for ignition target designs, Physics of Plasmas 21 (2014), 012704-1/012704-7

35. Gu Jian-Fa, Fan Zheng-Feng, Dai Zhen-Sheng, Ye Wen-Hua, Pei Wen-Bing, Zhu Shao-Ping, Studying Validity of Single-Fluid Model in Inertial Confinement Fusion, Communications in Theoretical Physics 61 ( 2014), 370/376.  

36. Wei-wu Wang, Hong-bo Cai, Qing Jia and Shao-ping Zhu, Collisional effects on the generation of fast electrons in fast ignition scheme, Phys. Plasmas 20 (2013), 012703-1/012703-8

37. Hong-bo Cai, Shao-ping Zhu, and X. T. He, Effects of the imposed magnetic field on the production and transport of relativistic electron beams, Phys. Plasmas 20 (2013), 072701-1/072701-10.

38. J. W. Li, W. B. Pei, X. T. He, J. H. Li, W. D. Zheng, S. P. Zhu, and W. Kang, Preheat of radiative shock in double-shell ignition targets, Phys. Plasmas 20 (2013), 082707-1/082707-6.

39. H. Zhang, S. Z. Wu, C. T. Zhou, S. P. Zhu, and X. T. He, Study on longitudinal dispersion relation in one-dimensional relativistic plasma: Linear theory and Vlasov simulation, Phys. Plasmas 20 (2013), 092112-1/092112-6.

40. Zhengfeng Fan, Shaoping Zhu, Wenbing Pei, Wenhua Ye, Meng Li, Xiaowen Xu, Junfeng Wu, Zhensheng Dai and Lifeng Wang, Numerical investigation on the stabilization of the deceleration phase Rayleigh-Taylor instability due to alpha particle heating in ignition target , Europhysics Letters 99 (2012), 65003-1/65003-6.

41. Hong-bo Cai, Shao-ping Zhu, Mo Chen, Si-zhong Wu, X. T. He, and Kunioki Mima, Magnetic-field generation and electron-collimation analysis for propagating fast electron beams in overdense plasmas£¬Phys. Rev. E 83 (2011), 036408 -1/036408-7. 

42. Hong-bo Cai, Shao-ping Zhu, Mo Chen, Si-zhong Wu, X. T. He, and Kunioki Mima, Erratum: Magnetic-field generation and electron-collimation analysis for propagating fast electron beams in overdense plasmas [Phys. Rev. E 83, 036408 (2011)], Phys. Rev. E 85 (2012), 019903(E).

43. Hongbo Cai, Shao-ping Zhu, X. T. He et al., Magnetic collimation of fast electrons in specially engineered targets irradiated by ultraintense laser pulses, Phys. Plasmas 18 (2011), 023106-1/023106-8.

44. Sizhong Wu, Cangtao Zhou, Shao-ping Zhu, Hua Zhang and Xiantu He, Relativistic kinetic model for energy deposition on intense laser-driven electrons in fast ignition scenario, Phys. Plasmas 18 (2011)£¬022703-1/022703-9.

45. Sizhong Wu, Cangtao Zhou and Shao-ping Zhu£¬Effect of density profile on beam control of intense laser-generated fast electrons, Phys. Plasmas 17 (2010)£¬063103-1/063103-7.

46. Zeyao Mo, Aiqing Zhang, Xiaolin Cao, Qingkai Liu, Xiaowen Xu, Hengbin An, Wenbing Pei, Shaoping Zhu, JASMIN: a parallel software infrastructure for scientific computing, Frontiers of Computer Science in China 4 (2010), 480/488.

47. Hong-bo Cai, Kunioki Mima, Atsushi Sunahara, Tomoyuki Johzaki, Hideo Nagatomo, Shao-ping Zhu, and X. T. He, Prepulse effects on the generation of high energy electrons in fast ignition scheme, Phys. Plasmas 17 (2010)£¬023106-1/023106-8.

48. Sizhong Wu, Cangtao Zhou, X. T. He and Shao-ping Zhu, Generation of strong magnetic fields from laser interaction with two-layer targets, Laser and Particle Beams 27 (2009)£¬471/474.

49. Shao-ping Zhu, Wenbing Pei, Yan Xu, Peijun Gu, Ke Lan, Wenhua Ye, Junfeng Wu, Jinghong Li Yaoming Gao, Chunyang Zheng, Shuanggui Li, Zeyao Mo, Jun Yan and Weiyan Zhang, Numerical Simulation on Laser Fusion in China, 6TH  International Conference on Atomic and Molecular Data and Their Applications, edited by Shao-ping Zhu and Jun Yan (Melville, New York), AIP Conference Proceedings 1125 (2009), 141/153.

50. Sizhong Wu, Zhanjun Liu, Cangtao Zhou and Shao-ping Zhu, Density effects on collimation of energetic electron beams driven by two intense laser pulses, Phys. Plasmas 16 (2009)£¬043106-1/043106-7.

51. ²ÜСÁÖ£¬Ö£´ºÑô£¬ÕÅ°®Ç壬ÖìÉÙƽ£¬ÄªÔòÒ¢£¬Ð¤Àö£¬ÃæÏòÊýǧ´¦ÀíÆ÷µÄÈýάµÈÀë×ÓÌåÁ£×ÓÄ£Äâ³ÌÐòÑÐÖÆ£¬×ÔÈ»¿Æѧ½øÕ¹ 19£¨2009£©£¬544/550¡£

52. Z.J. Liu, Shao-ping Zhu, L.H. Cao, and C.Y. Zheng, Comparison of the analytical and simulation results of the equilibrium beam profile£¬Phys. Plasmas 14 (2007)£¬103111-1/103111-4.

53. Hong-bo Cai, Wei Yu, Shao-ping Zhu£¬Cang-tao Zhou£¬Generation of strong quasistatic magnetic fields in interaction of ultraintense and short laser pulses with overdense plasma targets, Phys. Rev. E 76 (2007), 036403-1/ 036403-7.

54. Shao-ping Zhu and Weiyan Zhang, Overview of Computer Simulation on Laser Fusion in China, Journal of the Korean Physical Society 49, Supplementary Issue (2006)£¬S33/S37.

55. Hong-bo Cai, Wei Yu, Shao-ping Zhu£¬Chun-yang Zheng£¬ Short-pulse laser absorption via J ¡Á B heating in ultrahigh intensity laser plasma interaction, Phys. Plasmas 13 (2006), 113105-1/113105-6.

56. Hong-bo Cai, Wei Yu, Shao-ping Zhu£¬Chun-yang Zheng, Li-hua Cao£¬Bin Li, Z. Y. Chen and A. Bogerts, Short-pulse laser absorption in very steep plasma density gradients, Phys. Plasmas 13 (2006), 094504-1/094504-4

57. Bin Qiao, X. T. H, Shao-ping Zhu£¬Fluid theory for quasistatic magnetic field generation in intense laser plasma interaction£¬Phys. Plasmas 13 (2006)£¬053106-1/ 053106-7.

58. Z.J. Liu, Shao-ping Zhu, L.H. Cao, C.Y. Zheng, C.T. Zhou and Bin Li, Self-organization of plasma due to electron beam instability£¬Phys. Plasmas 13 (2006)£¬053103-1/ 053103-5.

59. Hong-bo Cai, Wei Yu, Shao-ping Zhu, Chun-yang Zheng, Li-hua Cao, and Wen-bing Pei, Vacuum heating in the interaction of ultrashort, relativistically strong laser pulses with solid targets, Phys. Plasmas 13 (2006)£¬063106-1/ 063108-6.

60. Hong-bo Cai, Shao-ping Zhu, and Chun-yang Zheng, Xian-tu He, Ji-wei Li, Effects of beam energy spread on the Weibel Instability in fast ignitor scenarios£¬Chin. Phys. Lett. 23 (2006), 161/164.

61. Bin Qiao, X. T. H, Shao-ping Zhu£¬Fluid theory of magnetic-field generation in intense laser-plasma interaction£¬Europhysics Letters 72 (2005)£¬955-961.

62. Bin Qiao, X. T. H,  Shao-ping Zhu and C. Y. Zheng, Electron acceleration in combined intense laser fields and self-consistent quasistatic fields in plasma, Phys. Plasmas 12 (2005), 083102/ 083102-10.

63. Bin Qiao, Shao-ping Zhu, C. Y. Zheng and X. T. He, Quasistatic magnetic and electric fields generated in intense laser plasma interaction, Phys. Plasmas 12 (2005), 053104/ 053104-12.

64. C. Y. Zheng, X. T. He and Shao-ping Zhu, Magnetic field generation and relativistic electron dynamics in circularly polarized intense laser interaction with dense plasma, Phys. Plasmas 12 (2005), 044505/ 044505-4.

65. Hong Bo Cai and Shao-ping Zhu, Stimulated Ramman Scattering in Bi-temperature Vlasov Plasma, Chinese Phys. Lett. 21 (2004), 891/894.

66. ÅíÖÒÁÖ£¬ÖìÉÙƽ£¬Åöײ¶ÔÊܼ¤RammanÉ¢ÉäµÄÓ°Ï죬ÎïÀíѧ±¨52£¨2003£©£¬2500/2507¡£

67. Shao-ping Zhu, C. Y. Zheng and X. T. He, A theoretical model for spontaneous magnetic field in intense laser plasma interaction£¬Phys. Plasmas 10 (2003), 4166/4168.

68. Tieqiang Chang, Yongkun Ding, Dongxian Lai, Tianxuan Huan, Shao-ping Zhu£¬Zhijian Zheng, Guangyu Wang, Yongmin Zheng, Xiantu He, Wenbing Pei, Qingsheng Duan, Weiyan Zhang, Tinggui Feng, Guangnan Chen and Peijun Gu, Laser hohlraum coupling eficiency on the Shenguang II facility, Phys. Plasmas 9 (2002), 4744/4748.

69. X. T. He, Chunyang Zheng and Shao-ping Zhu, Harmonic modulation instability and spatiotemporal chaos, Phys. Rev. E 66 (2002), 037201-1/037201-4.

70. Shao-ping Zhu, X. T. He and Chunyang Zheng, Slow-time-scale magnetic fields driven by fast-time-scalewaves in an underdense relativistic Vlasov plasma, Phys. Plasmas 8 (2001), 321/328.

71. Shao-ping Zhu and Chunyang Zheng, Slow-time-scale magnetic fields in underdense plasma, Progress of Theoretical Physics Supplement N0.138 (2000), 744/745.

72. ÖìÉÙƽ£¬¹ÅÅà¿¡£¬¼¤¹â°ÐñîºÏ¹ý³ÌÖеļ¤¹âÄÜÁ¿³Á»ý·½³Ì£¬Ç¿¼¤¹âÓëÁ£×ÓÊø 11£¨1999£©£¬687/691¡£

73. Shao-ping Zhu and Peijun Gu, A heat transport model including the effect of non-Maxwellian electron distribution and its application in laser produced plasma, Chinese Phys. Lett. 7 (1999), 520/522.

74. Shao-ping Zhu£¬Kinetic simulation study on  one dimensional collisional bounded  plasma£¬Nuclear Science and Techniques 10 (1999), 155/160.

75. Shao-ping Zhu, Ritoku Horiuchi, Tetsuya Sato and Complexity Simulation Group,"Self-organization process of a magnetohydrodynamic plasma in the presence of thermal conduction", Phys. Plasmas 3 (1996), 2821/ 2823.

76. Shao-ping Zhu, Ritoku Horiuchi, Tetsuya Sato and Complexity Simulation Group,"Non-Taylor magnetohydrodynamic self-organization ", Phys. Rev. E 51 (1995), 6047/6054.

77. Shao-ping Zhu and X. T. He, "Ponderomotive force in unmagnetized Vlasov plasma", Plasma Phys. Controlled Fusion 36 (1993), 291/299.

78. Shao-ping Zhu, "Slow-time-scale magnetic fields driven by fast-time-scale electric fields", Phys. Fluids B: plasma physics 5 (1993), 1024/1026.

79. Shao-ping Zhu, "Equilibrium for Compton scattering media", Can. J. Phys. 70 (1992), 1312/1313.

80. Shao-ping Zhu and X. T. He, "Relative diffusion and formation of clumps in phase space of electrons in localized Langmuir fields", Phys. Rev. A 43 (1991), 1988/1993.