吉亮亮 男 博导 中国科学院上海光学精密机械研究所
电子邮件: jill@siom.ac.cn
通信地址: 上海市嘉定区清河路390号
邮政编码:
电子邮件: jill@siom.ac.cn
通信地址: 上海市嘉定区清河路390号
邮政编码:
研究领域
a) 强激光等离子体物理与前沿应用
b) 极端超强激光物理,如强场量子电动力学效应、激光驱动反物质/暗物质粒子产生等
c) 激光驱动高能量密度物理与核物理
招生信息
招生专业
070207-光学070204-等离子体物理070201-理论物理
招生方向
激光等离子体物理强场激光物理强场量子电动力学
教育背景
2006-09--2011-06 中国科学院上海光学精密机械研究所 理学博士2002-09--2006-07 中国科学技术大学 理学学士
工作经历
工作简历
2016-08~现在, 中国科学院上海光学精密机械研究所, 研究员2012-09~2016-08,美国俄亥俄州立大学, 博士后研究员2012-05~2014-06,德国杜塞尔多夫大学, 洪堡学者2011-07~2012-04,中国科学院上海光学精密机械研究所, 助理研究员
社会兼职
2021-12-18-2024-12-31,High Power Laser Science and Engeering期刊, 编委
2021-06-27-2023-05-31,Plasma Science and Technology期刊, 编委
2020-08-31-2025-08-31,强激光与粒子束期刊, 编委
2016-12-31-2021-12-30,中国激光杂志社, 青年编委
2021-06-27-2023-05-31,Plasma Science and Technology期刊, 编委
2020-08-31-2025-08-31,强激光与粒子束期刊, 编委
2016-12-31-2021-12-30,中国激光杂志社, 青年编委
教授课程
强场激光等离子体物理
专利与奖励
奖励信息
(1) 上海市自然科学一等奖, 一等奖, 省级, 2019(2) Springer outstanding thesis award, 其他, 2013(3) 中科院院长特别奖, 院级, 2012(4) 中国院优秀博士学位论文, 院级, 2012(5) 中科院卢嘉锡青年人才奖, 院级, 2012(6) 蔡诗东等离子体物理奖, 其他, 2011
专利成果
[1] 秦承宇, 张辉, 李顺, 李昂骁, 吉亮亮, 沈百飞. 激光与微通道靶准直调节系统及准直调节方法. CN: CN113205739A, 2021-08-03.[2] 李顺, 沈百飞, 徐建彩, 范路林, 吉亮亮, 徐同军. 基于SiPM的超快伽马射线实时探测装置. CN: CN112596096A, 2021-04-02.[3] 李顺, 沈百飞, 徐建彩, 吉亮亮, 徐同军. 一种超快伽马射线脉宽探测装置. CN: CN112539848A, 2021-03-23.[4] 沈百飞, 李顺, 张辉, 李昂骁, 秦承宇, 吉亮亮. 基于激光加速器的单粒子效应测试装置. CN: CN112383998A, 2021-02-19.
出版信息
发表论文
[1] Yan, Xue, Wu, Yitong, Geng, Xuesong, Zhang, Hui, Shen, Baifei, Ji, Liangliang. Enhanced polarized proton acceleration driven by femtosecond laser pulses irradiating a micro-structured solid-gas target. PLASMA PHYSICS AND CONTROLLED FUSION[J]. 2023, 65(3): [2] 王青松, 秦承宇, 张辉, 李顺, 李昂骁, 王能文, 陆效明, 李进峰, 许荣杰, 王乘, 梁晓燕, 冷雨欣, 沈百飞, 吉亮亮. Spatial distribution modulation of laser-accelerated charged particles with micro-tube structures. Physics of Plasmas[J]. 2023, 30(4): 043105-, https://pubs.aip.org/aip/pop/article/30/4/043105/2882972/Spatial-distribution-modulation-of-laser.[3] Lulin Fan, Tongjun Xu, Shun Li, Zhangli Xu, Jiancai Xu, Jianqiang Zhu, Baifei Shen, Liangliang Ji. Collimated gamma beams with high peak flux driven by laser-accelerated electrons. HIGH POWER LASER SCIENCE AND ENGINEERING[J]. 2023, 11: https://doaj.org/article/cd3f2de977714de09952a6324140d327.[4] Han, Qianqian, Geng, Xuesong, Shen, Baifei, Xu, Zhizhan, Ji, Liangliang. Ultra-fast polarization of a thin electron layer in the rotational standing-wave field driven by double ultra-intense laser pulses. NEW JOURNAL OF PHYSICS[J]. 2022, 24(6): http://dx.doi.org/10.1088/1367-2630/ac740f.[5] Wang, W Q, Lei, S H, Geng, X S, Shen, B F, Bu, Z G, Ji, L L. Triple-vortex bremsstrahlung. NEW JOURNAL OF PHYSICS[J]. 2022, 24(4): http://dx.doi.org/10.1088/1367-2630/ac639c.[6] Guo, Yinlong, Geng, Xuesong, Ji, Liangliang, Shen, Baifei, Li, Ruxin. Improving the accuracy of hard photon emission by sigmoid sampling of the quantum-electrodynamic table in particle-in-cell Monte Carlo simulations. PHYSICAL REVIEW E[J]. 2022, 105(2): http://dx.doi.org/10.1103/PhysRevE.105.025309.[7] CYQin, HZhang, SLi, SHZhai, AXLi, JYQian, JYGui, FXWu, ZXZhang, YXu, XYLiang, YXLeng, BFShen, LLJi, RXLi. Mapping non-laminar proton acceleration in laser-driven target normal sheath field. High Power Laser Science and Engineering[J]. 2022, 10(1): 10-16, http://lib.cqvip.com/Qikan/Article/Detail?id=7107423274.[8] 秦承宇, 张辉, 李顺, 王能文, 李昂骁, 范路林, 陆效明, 李进峰, 许荣杰, 王乘, 梁晓燕, 冷雨欣, 沈百飞, 吉亮亮, 李儒新. High efficiency laser-driven proton sources using 3D-printed micro-structure. Communications Physics[J]. 2022, 5(1): 124-, https://www.nature.com/articles/s42005-022-00900-8.[9] Geng, Xuesong, Ji, Liangliang, Shen, Baifei. Quasimonochromatic Bright Gamma-ray Generation from Synchronized Compton Scattering via Azimuthal Spatial-Temporal Coupling. PHYSICAL REVIEW APPLIED[J]. 2022, 17(2): http://dx.doi.org/10.1103/PhysRevApplied.17.024055.[10] 王伟清, 刘世宇, 雷少虎, 耿学松, 沈百飞, 步志刚, 吉亮亮. Finite orbital-angular-momentum carried by the final electron and photon in plane-wave electron-nucleus bremsstrahlung. PHYSICAL REVIEW RESEARCH[J]. 2022, 4: 023084-, [11] Li, A X, Qin, C Y, Zhang, Hui, Li, S, Fan, L L, Wang, Q S, Xu, T J, Wang, N W, Yu, L H, Xu, Y, Liu, Y Q, Wang, C, Wang, X L, Zhang, Z X, Liu, X Y, Bai, P L, Gan, Z B, Zhang, X B, Wang, X B, Fan, C, Sun, Y J, Tang, Y H, Yao, B, Liang, X Y, Leng, Y X, Shen, B F, Ji, L L, Li, R X, Xu, Z Z. Acceleration of 60 MeV proton beams in the commissioning experiment of the SULF-10 PW laser. HIGH POWER LASER SCIENCE AND ENGINEERING[J]. 2022, 10(4): 36-44, [12] Huang, Shan, Shen, Baifei, Bu, Zhigang, Zhang, Xiaomei, Ji, Liangliang, Zhai, Shuhua. Axion-like particle generation in laser-plasma interaction. PHYSICA SCRIPTA[J]. 2022, 97(10): [13] Zhang Lingang, Ji Liangliang, Shen Baifei. Intense harmonic generation driven by a relativistic spatiotemporal vortex beam. HIGH POWER LASER SCIENCE AND ENGINEERING[J]. 2022, 10(6): http://sciencechina.cn/gw.jsp?action=detail.jsp&internal_id=7414556&detailType=1.[14] Han, Qianqian, Geng, Xuesong, Shen, Baifei, Ji, LiangLiang, Xu, Zhizhan. Generation of dense and well-collimated positron beam via ultra-intense laser colliding with a flying plasma layer. PLASMA PHYSICS AND CONTROLLED FUSION[J]. 2022, 64(4): http://dx.doi.org/10.1088/1361-6587/ac463c.[15] Yan, Xue, Ji, Liangliang. Spin-polarized proton acceleration by an intense laser pulse with a foil-gas target. LASER PHYSICS LETTERS[J]. 2022, 19(10): [16] 沈百飞, 吉亮亮, 张晓梅, 步志刚, 徐建彩. 强场X射线激光物理. 物理学报[J]. 2021, 70(8): 55-72, http://lib.cqvip.com/Qikan/Article/Detail?id=7104449538.[17] 吉亮亮, 耿学松, 伍艺通, 沈百飞, 李儒新. 超强激光驱动的辐射反作用力效应与极化粒子加速. 物理学报[J]. 2021, 70(8): 226-247, http://lib.cqvip.com/Qikan/Article/Detail?id=7104449554.[18] Wu, Yitong, Ji, Liangliang, Li, Ruxin. On the upper limit of laser intensity attainable in nonideal vacuum. PHOTONICS RESEARCH[J]. 2021, 9(4): 541-547, https://www.webofscience.com/wos/woscc/full-record/WOS:000636997400027.[19] Zhang, Lingang, Shen, Baifei, Bu, Zhigang, Zhang, Xiaomei, Ji, Liangliang, Huang, Shan, Xiriai, M, Xu, Zhangli, Liu, Chen, Xu, Zhizhan. Vortex Harmonic Generation by Circularly Polarized Gaussian Beam Interacting with Tilted Target. PHYSICAL REVIEW APPLIED[J]. 2021, 16(1): http://dx.doi.org/10.1103/PhysRevApplied.16.014065.[20] Shen BaiFei, Ji LiangLiang, Zhang XiaoMei, Bu ZhiGang, Xu JianCai. High field X-ray laser physics. ACTA PHYSICA SINICA[J]. 2021, 70(8): http://dx.doi.org/10.7498/aps.70.20210096.[21] Lei, Shaohu, Bu, Zhigang, Wang, Weiqing, Shen, Baifei, Ji, Liangliang. Generation of relativistic positrons carrying intrinsic orbital angular momentum. PHYSICAL REVIEW D[J]. 2021, http://arxiv.org/abs/2109.02234.[22] Ji LiangLiang, Geng XueSong, Wu YiTong, Shen BaiFei, Li RuXin. Laser-driven radiation-reaction effect and polarized particle acceleration. ACTA PHYSICA SINICA[J]. 2021, 70(8): http://dx.doi.org/10.7498/aps.70.20210091.[23] 步志刚, 吉亮亮, 雷少虎, 胡华雨, 张晓梅, 沈百飞. Twisted Breit-Wheeler electron-positron pair creation via vortex gamma photons. Phys. Rev. Research[J]. 2021, [24] Htzen, Anna, Thomas, Johannes, Lehrach, Andreas, Rakitzis, T Peter, Pukhov, Alexander, Ji, Liangliang, Wu, Yitong, Engels, Ralf, Bscher, Markus. Simulation of Polarized Beams from Laser-Plasma Accelerators. 2020, http://arxiv.org/abs/2002.02211.[25] Wu, Yitong, Ji, Liangliang, Geng, Xuesong, Thomas, Johannes, Buescher, Markus, Pukhov, Alexander, Huetzen, Anna, Zhang, Lingang, Shen, Baifei, Li, Ruxin. Spin Filter for Polarized Electron Acceleration in Plasma Wakefields. PHYSICAL REVIEW APPLIED[J]. 2020, 13(4): https://www.webofscience.com/wos/woscc/full-record/WOS:000528534700004.[26] Geng, X S, Ji, L L, Shen, B F, Feng, B, Guo, Z, Han, Q Q, Qin, C Y, Wang, N W, Wang, W Q, Wu, Y T, Yan, X, Yu, Q, Zhang, L G, Xu, Z Z. Spin-dependent radiative deflection in the quantum radiation-reaction regime. NEW JOURNAL OF PHYSICS[J]. 2020, 22(1): http://dx.doi.org/10.1088/1367-2630/ab623b.[27] Buscher, Markus, Huetzen, Anna, Ji, Liangliang, Lehrach, Andreas. Generation of polarized particle beams at relativistic laser intensities. HIGH POWER LASER SCIENCE AND ENGINEERING[J]. 2020, 8(4): 44-58, http://dx.doi.org/10.1017/hpl.2020.35.[28] Xu, Zhangli, Yi, Longqing, Shen, Baifei, Xu, Jiancai, Ji, Liangliang, Xu, Tongjun, Zhang, Lingang, Li, Shun, Xu, Zhizhan. Driving positron beam acceleration with coherent transition radiation. COMMUNICATIONS PHYSICS[J]. 2020, 3(1): http://dx.doi.org/10.1038/s42005-020-00471-6.[29] Thomas, Johannes, Huetzen, Anna, Lehrach, Andreas, Pukhov, Alexander, Ji, Liangliang, Wu, Yitong, Geng, Xuesong, Buescher, Markus. Scaling laws for the depolarization time of relativistic particle beams in strong fields. PHYSICAL REVIEW ACCELERATORS AND BEAMS[J]. 2020, 23(6): https://doaj.org/article/e7eececd645541a9a1ebd4d2e322262c.[30] Ji, L L, Snyder, J, Shen, B F. Single-pulse laser-electron collision within a micro-channel plasma target. PLASMA PHYSICS AND CONTROLLED FUSION[J]. 2019, 61(6): https://www.webofscience.com/wos/woscc/full-record/WOS:000467822100001.[31] Geng, X S, Ji, L L, Shen, B F, Feng, B, Guo, Z, Yu, Q, Zhang, L G, Xu, Z Z. Quantum reflection above the classical radiation-reaction barrier in the quantum electro-dynamics regime. COMMUNICATIONS PHYSICS[J]. 2019, 2(1): https://doaj.org/article/da1f1c3d92ec4b609d1e7693ffee8855.[32] Wu, Yitong, Ji, Liangliang, Geng, Xuesong, Yu, Qin, Wang, Nengwen, Feng, Bo, Guo, Zhao, Wang, Weiqing, Qin, Chengyu, Yan, Xue, Zhang, Lingang, Thomas, Johannes, Huetzen, Anna, Buescher, Markus, Rakitzis, T Peter, Pukhov, Alexander, Shen, Baifei, Li, Ruxin. Polarized electron-beam acceleration driven by vortex laser pulses. NEW JOURNAL OF PHYSICS[J]. 2019, 21: https://www.webofscience.com/wos/woscc/full-record/WOS:000477660100002.[33] Wu, Yitong, Ji, Liangliang, Geng, Xuesong, Yu, Qin, Wang, Nengwen, Feng, Bo, Guo, Zhao, Wang, Weiqing, Qin, Chengyu, Yan, Xue, Zhang, Lingang, Thomas, Johannes, Huetzen, Anna, Pukhov, Alexander, Buescher, Markus, Shen, Baifei, Li, Ruxin. Polarized electron acceleration in beam-driven plasma wakefield based on density down-ramp injection. PHYSICAL REVIEW E[J]. 2019, 100(4): https://www.webofscience.com/wos/woscc/full-record/WOS:000489828800008.[34] Feng, B, Qin, C Y, Geng, X S, Yu, Q, Wang, W Q, Wu, Y T, Yan, X, Ji, L L, Shen, B F. The emission of gamma-Ray beams with orbital angular momentum in laser-driven micro-channel plasma target. SCIENTIFIC REPORTS[J]. 2019, 9: [35] Guo, Zhao, Ji, Liangliang, Yu, Qin, Feng, Bo, Geng, Xuesong, Zhang, Lingang, Wang, Weiqing, Shen, Baifei. Leveraging radiation reaction via laser-driven plasma fields. PLASMA PHYSICS AND CONTROLLED FUSION[J]. 2019, 61(6): http://dx.doi.org/10.1088/1361-6587/ab140b.[36] Snyder, J, Ji, L L, George, K M, Wills, C, Cochran, G E, Daskalova, R L, Handler, A, Rubin, T, Poole, P L, Nasir, D, Zingale, A, Chowdhury, E, Shen, B F, Schumacher, D W. Relativistic laser driven electron accelerator using micro-channel plasma targets. PHYSICS OF PLASMAS[J]. 2019, 26(3): http://dx.doi.org/10.1063/1.5087409.[37] Gong, Weifeng, Shen, Baifei, Zhang, Xiaomei, Ji, Liangliang, Zhang, Lingang. Asymmetric optical vortex in plasma density gradient. PLASMA PHYSICS AND CONTROLLED FUSION[J]. 2019, 61(12): http://dx.doi.org/10.1088/1361-6587/ab49cc.[38] Liu, Chen, Shen, Baifei, Zhang, Xiaomei, Ji, Liangliang, Bu, Zhigang, Wang, Wenpeng, Yi, Longqing, Zhang, Lingang, Xu, Jiancai, Xu, Tongjun, Pei, Zhikun. Ultra-bright, well-collimated, GeV gamma-ray production in the QED regime. PHYSICS OF PLASMAS[J]. 2018, 25(2): http://dx.doi.org/10.1063/1.5005077.[39] Ji, Liangliang, Shen, Baifei, Zhang, Xiaomei. Transparency of near-critical density plasmas under extreme laser intensities. NEW JOURNAL OF PHYSICS[J]. 2018, 20: https://www.webofscience.com/wos/woscc/full-record/WOS:000432828700002.[40] Wu, Yitong, Ji, Lianglian, Zhang, Lingang, Guo, Zhao, Feng, Bo, Geng, Xuesong, Yu, Qin, Wang, Nengwen, Zhang, Xiaomei, Shen, Baifei, Li, Ruxin. Effects of adiation reaction on laser proton acceleration in the bubble regime. PHYSICS OF PLASMAS[J]. 2018, 25(9): http://dx.doi.org/10.1063/1.5042318.[41] Feng, B, Ji, L L, Shen, B F, Geng, X S, Guo, Z, Yu, Q, Xu, T J, Zhang, L G. Effects of micro-structures on laser-proton acceleration. PHYSICS OF PLASMAS[J]. 2018, 25(10): http://dx.doi.org/10.1063/1.5037496.[42] Guo, Zhao, Shen, Baifei, Zhang, Xiaomei, Ji, Liangliang, Zhang, Lingang, Liu, Chen. Autocorrelation pulse-duration measurement of relativistic femtosecond laser. PHYSICS OF PLASMAS[J]. 2018, 25(7): http://dx.doi.org/10.1063/1.5027781.[43] Xu, Jiancai, Shen, Baifei, Zhang, Xiaomei, Shi, Yin, Ji, Liangliang, Zhang, Lingang, Xu, Tongjun, Wang, Wenpeng, Zhao, Xueyan, Xu, Zhizhan. Terawatt-scale optical half-cycle attosecond pulses. SCIENTIFIC REPORTS[J]. 2018, 8(1): https://doaj.org/article/51c8bb2df1294697b03825a6ff30a4c7.[44] Shen, Baifei, Bu, Zhigang, Xu, Jiancai, Xu, Tongjun, Ji, Liangliang, Li, Ruxin, Xu, Zhizhan. Exploring vacuum birefringence based on a 100 PW laser and an x-ray free electron laser beam. PLASMA PHYSICS AND CONTROLLED FUSION[J]. 2018, 60(4): https://www.webofscience.com/wos/woscc/full-record/WOS:000424775600001.[45] Ji, Liangliang, Jiang, Sheng, Pukhov, Alexander, Freeman, Richard, Akli, Kramer. Exploring novel target structures for manipulating relativistic laser-plasma interaction. HIGH POWER LASER SCIENCE AND ENGINEERING[J]. 2017, 5(2): https://www.webofscience.com/wos/woscc/full-record/WOS:000404593200001.[46] Akli, Kramer, Ji, Liangliang, Jiang, Sheng, Pukhov, Alexander, Freeman, Richard. Exploring novel target structures for manipulating relativistic laser-plasma interaction. HIGH POWER LASER SCI. ENG.[J]. 2017, 5: http://gateway.webofknowledge.com/gateway/Gateway.cgi?GWVersion=2&SrcApp=PARTNER_APP&SrcAuth=LinksAMR&KeyUT=WOS:000404593200001&DestLinkType=FullRecord&DestApp=ALL_WOS&UsrCustomerID=3a85505900f77cc629623c3f2907beab.[47] Liu, Chen, Shen, Baifei, Zhang, Xiaomei, Ji, Liangliang, Wang, Wenpeng, Xu, Jiancai, Zhao, Xueyan, Yi, Longqing, Shi, Yin, Zhang, Lingang, Xu, Tongjun, Pei, Zhikun, Xu, Zhizhan. Generation of ultra-intense gamma-ray train by QED harmonics. PHYSICS OF PLASMAS[J]. 2016, 23(8): http://dx.doi.org/10.1063/1.4961237.[48] Ji, Liangliang, Wang, Xiaofeng, Tajima, Toshiki, Xu, Zhizhan, Zhang, Xiaomei, Shen, Baifei, Shi, Yin, Zhang, Lingang. Intense harmonics generation with customized photon frequency and optical vortex. NEW J. PHYS.[J]. 2016, 18: http://gateway.webofknowledge.com/gateway/Gateway.cgi?GWVersion=2&SrcApp=PARTNER_APP&SrcAuth=LinksAMR&KeyUT=WOS:000384138100001&DestLinkType=FullRecord&DestApp=ALL_WOS&UsrCustomerID=3a85505900f77cc629623c3f2907beab.[49] Liu, Chen, Shen, Baifei, Zhang, Xiaomei, Shi, Yin, Ji, Liangliang, Wang, Wenpeng, Yi, Longqing, Zhang, Lingang, Xu, Tongjun, Pei, Zhikun, Xu, Zhizhan. Generation of gamma-ray beam with orbital angular momentum in the QED regime. PHYSICS OF PLASMAS[J]. 2016, 23(9): http://dx.doi.org/10.1063/1.4963396.[50] Jiang, S, Ji, L L, Audesirk, H, George, K M, Snyder, J, Krygier, A, Poole, P, Willis, C, Daskalova, R, Chowdhury, E, Lewis, N S, Schumacher, D W, Pukhov, A, Freeman, R R, Akli, K U. Microengineering Laser Plasma Interactions at Relativistic Intensities. PHYSICAL REVIEW LETTERS[J]. 2016, 116(8): https://www.webofscience.com/wos/woscc/full-record/WOS:000370817400011.[51] Snyder, J, Ji, L L, Akli, K U. Enhancement of laser intensity and proton acceleration using micro-tube plasma lens targets. PHYSICS OF PLASMAS[J]. 2016, 23(12): http://dx.doi.org/10.1063/1.4972577.[52] Pei, Zhikun, Shen, Baifei, Shi, Yin, Ji, Liangliang, Wang, Wenpeng, Zhang, Xiaomei, Zhang, Lingang, Xu, Tongjun, Liu, Chen. Quasi-stationary fluid theory of the hole-boring process. PHYS. PLASMAS[J]. 2016, 23(4): http://gateway.webofknowledge.com/gateway/Gateway.cgi?GWVersion=2&SrcApp=PARTNER_APP&SrcAuth=LinksAMR&KeyUT=WOS:000375855500059&DestLinkType=FullRecord&DestApp=ALL_WOS&UsrCustomerID=3a85505900f77cc629623c3f2907beab.[53] Zhang, Lingang, Liu, Chen, Shen, Baifei, Zhang, Xiaomei, Ji, Liangliang, Wang, Wenpeng, Xu, Jiancai, Zhao, Xueyan, Yi, Longqing, Shi, Yin, Xu, Tongjun, Pei, Zhikun, Xu, Zhizhan. Generation of ultra-intense gamma-ray train by QED harmonics. PHYS. PLASMAS[J]. 2016, 23(8): http://gateway.webofknowledge.com/gateway/Gateway.cgi?GWVersion=2&SrcApp=PARTNER_APP&SrcAuth=LinksAMR&KeyUT=WOS:000383878100084&DestLinkType=FullRecord&DestApp=ALL_WOS&UsrCustomerID=3a85505900f77cc629623c3f2907beab.[54] Pei, Zhikun, Shen, Baifei, Shi, Yin, Ji, Liangliang, Wang, Wenpeng, Zhang, Xiaomei, Zhang, Lingang, Xu, Tongjun, Liu, Chen. Quasi-stationary fluid theory of the hole-boring process. PHYSICS OF PLASMAS[J]. 2016, 23(4): http://dx.doi.org/10.1063/1.4946873.[55] Zhang, Xiaomei, Shen, Baifei, Shi, Yin, Zhang, Lingang, Ji, Liangliang, Wang, Xiaofeng, Xu, Zhizhan, Tajima, Toshiki. Intense harmonics generation with customized photon frequency and optical vortex. NEW JOURNAL OF PHYSICS[J]. 2016, 18: https://www.webofscience.com/wos/woscc/full-record/WOS:000384138100001.[56] Ji, L L, Snyder, J, Pukhov, A, Freeman, R R, Akli, K U. Towards manipulating relativistic laser pulses with micro-tube plasma lenses. SCIENTIFIC REPORTS[J]. 2016, 6: https://www.webofscience.com/wos/woscc/full-record/WOS:000372052300001.[57] Pei, Zhikun, Liu, Chen, Shen, Baifei, Zhang, Xiaomei, Shi, Yin, Ji, Liangliang, Wang, Wenpeng, Yi, Longqing, Zhang, Lingang, Xu, Tongjun, Xu, Zhizhan. Generation of gamma-ray beam with orbital angular momentum in the QED regime. PHYS. PLASMAS[J]. 2016, 23(9): http://gateway.webofknowledge.com/gateway/Gateway.cgi?GWVersion=2&SrcApp=PARTNER_APP&SrcAuth=LinksAMR&KeyUT=WOS:000385633200082&DestLinkType=FullRecord&DestApp=ALL_WOS&UsrCustomerID=3a85505900f77cc629623c3f2907beab.[58] Zhang, Lingang, Shen, Baifei, Xu, Jiancai, Ji, Liangliang, Zhang, Xiaomei, Wang, Wenpeng, Zhao, Xueyan, Yi, Longqing, Yu, Yahong, Shi, Yin, Xu, Tongjun, Xu, Zhizhan. High quality electron bunch generation with CO2-laser-plasma interaction. PHYSICS OF PLASMAS[J]. 2015, 22(2): http://dx.doi.org/10.1063/1.4906883.[59] Ji Liangliang. 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发表著作
(1) Ion acceleration and extreme light field generation based on ultra-short and ultra-intense lasers, Springer, 2014-01, 第 1 作者