Simulations on the multi-shell target ignition driven by radiation pulse in Z-pinch dynamic hohlraum

doi:10.1088/1674-1056/ac01c2

中国物理B ›› 2021, Vol. 30 ›› Issue (11): 115201-115201.doi: 10.1088/1674-1056/ac01c2

Simulations on the multi-shell target ignition driven by radiation pulse in Z-pinch dynamic hohlraum

Shi-Jia Chen(陈诗佳)¹, Yan-Yun Ma(马燕云)^2,3,†, Fu-Yuan Wu(吴福源)^2,4,‡, Xiao-Hu Yang(杨晓虎)^1,2, Yun Yuan(袁赟)¹, Ye Cui(崔野)¹, and Rafael Ramis⁵

1 Department of Physics, National University of Defense Technology, Changsha 410073, China;
2 IFSA Collaborative Innovation Center, Shanghai Jiao Tong University, Shanghai 200240, China;
3 College of Advanced Interdisciplinary Studies, National University of Defense Technology, Changsha 410073, China;
4 Laboratory of Laser Plasmas School of Physics and Astronomy, Shanghai Jiao Tong University, Shanghai 200240, China;
5 E. T. S. I. Aeronáutica y del Espacio, Universidad Politécnica de Madrid, Spain

收稿日期:2021-03-20 修回日期:2021-04-30 接受日期:2021-05-16 出版日期:2021-10-13 发布日期:2021-11-06
通讯作者: Yan-Yun Ma, Fu-Yuan Wu E-mail:yanyunma@126.com;fuyuan.wu@sjtu.edu.cn
基金资助:
Project supported by the Science Challenge Project (Grant No. TZ2018001), the Strategic Priority Research Program of the Chinese Academy of Sciences (Grant Nos. XDA25051200 and XDA25050200), the National Natural Science Foundation of China (Grant Nos. 11705282 and 11775305), and Hunan Graduate Scientific Research Innovation Project (Grant No. CX20190001). R.R. has been supported by the spanish “Ministerio de Ciencia Innovación y Universidades” project RTI2018-098801-B-100, the Spanish “Ministerio de Economía y Competitividad” Project ENE2014-54960-R, and the EURO fusion Consortium project AWP15-ENR-01/CEA-02.

Simulations on the multi-shell target ignition driven by radiation pulse in Z-pinch dynamic hohlraum

Shi-Jia Chen(陈诗佳)¹, Yan-Yun Ma(马燕云)^2,3,†, Fu-Yuan Wu(吴福源)^2,4,‡, Xiao-Hu Yang(杨晓虎)^1,2, Yun Yuan(袁赟)¹, Ye Cui(崔野)¹, and Rafael Ramis⁵

1 Department of Physics, National University of Defense Technology, Changsha 410073, China;
2 IFSA Collaborative Innovation Center, Shanghai Jiao Tong University, Shanghai 200240, China;
3 College of Advanced Interdisciplinary Studies, National University of Defense Technology, Changsha 410073, China;
4 Laboratory of Laser Plasmas School of Physics and Astronomy, Shanghai Jiao Tong University, Shanghai 200240, China;
5 E. T. S. I. Aeronáutica y del Espacio, Universidad Politécnica de Madrid, Spain

Received:2021-03-20 Revised:2021-04-30 Accepted:2021-05-16 Online:2021-10-13 Published:2021-11-06
Contact: Yan-Yun Ma, Fu-Yuan Wu E-mail:yanyunma@126.com;fuyuan.wu@sjtu.edu.cn
Supported by:
Project supported by the Science Challenge Project (Grant No. TZ2018001), the Strategic Priority Research Program of the Chinese Academy of Sciences (Grant Nos. XDA25051200 and XDA25050200), the National Natural Science Foundation of China (Grant Nos. 11705282 and 11775305), and Hunan Graduate Scientific Research Innovation Project (Grant No. CX20190001). R.R. has been supported by the spanish “Ministerio de Ciencia Innovación y Universidades” project RTI2018-098801-B-100, the Spanish “Ministerio de Economía y Competitividad” Project ENE2014-54960-R, and the EURO fusion Consortium project AWP15-ENR-01/CEA-02.

摘要/Abstract

摘要： We present the first simulation results of a multi-shell target ignition driven by Z-pinch dynamic hohlraum radiation pulse. The radiation pulse is produced with a special Z-pinch dynamic hohlraum configuration, where the hohlraum is composed of a single metal liner, a low-Z plastic foam, and a high-Z metallic foam. The implosion dynamics of a hohlraum and a multi-shell target are investigated separately by the one-dimensional code MULTI-IFE. When the peak drive current is 50 MA, simulations suggest that an x-ray pulse with nearly constant radiation temperature (～ 310 eV) and a duration about 9 ns can be obtained. A small multi-shell target with a radius of 1.35 mm driven by this radiation pulse is able to achieve volumetric ignition with an energy gain (G) about 6.19, where G is the ratio of the yield to the absorbed radiation. Through this research, we better understand the effects of non-uniformities and hydrodynamics instabilities in Z-pinch dynamic hohlraum.

关键词: Z-pinch, dynamic hohlraum, radiation pulse, volumetric ignition

Abstract: We present the first simulation results of a multi-shell target ignition driven by Z-pinch dynamic hohlraum radiation pulse. The radiation pulse is produced with a special Z-pinch dynamic hohlraum configuration, where the hohlraum is composed of a single metal liner, a low-Z plastic foam, and a high-Z metallic foam. The implosion dynamics of a hohlraum and a multi-shell target are investigated separately by the one-dimensional code MULTI-IFE. When the peak drive current is 50 MA, simulations suggest that an x-ray pulse with nearly constant radiation temperature (～ 310 eV) and a duration about 9 ns can be obtained. A small multi-shell target with a radius of 1.35 mm driven by this radiation pulse is able to achieve volumetric ignition with an energy gain (G) about 6.19, where G is the ratio of the yield to the absorbed radiation. Through this research, we better understand the effects of non-uniformities and hydrodynamics instabilities in Z-pinch dynamic hohlraum.

Key words: Z-pinch, dynamic hohlraum, radiation pulse, volumetric ignition

中图分类号: (Z-pinches, plasma focus, and other pinch devices)

52.58.Lq

52.59.Qy (Wire array Z-pinches)

Shi-Jia Chen(陈诗佳), Yan-Yun Ma(马燕云), Fu-Yuan Wu(吴福源), Xiao-Hu Yang(杨晓虎), Yun Yuan(袁赟), Ye Cui(崔野), and Rafael Ramis. Simulations on the multi-shell target ignition driven by radiation pulse in Z-pinch dynamic hohlraum[J]. 中国物理B, 2021, 30(11): 115201-115201.

参考文献

[1] Hurricane O A, Callahan D A, Casey D T, Celliers P M, Cerjan C, Dewald E L, Dittrich T R, Döppner T, Hinkel D E, Berzak Hopkins L F, Kline J L, Le Pape S, Ma T, Macphee A G, Milovich J L, Pak A, Park H S, Patel P K, Remington B A, Salmonson J D, Springer P T and Tommasini R 2014 Nature 506 343
[2] Atzeni S and Meyer-ter-Vehn J 2004 The Physics of Inertial Fusion (Oxford: Oxford University Press)
[3] Lan K, Liu J, Li Z C, Xie X F, Huo W Y, Chen Y H, Ren G L, Zheng C Y, Yang D, Li S W, Yang Z W, Guo L, Li S, Zhang M Y, Han X Y, Zhai C L, Hou L F, Li Y K, Deng K L, Yuan Z, Zhan X Y, Wang F, Yuan G H, Zhang H J, Jiang B B, Huang L Z, Zhang W, Du K, Zhao R C, Li P, Wang W, Su J Q, Deng X W, Hu D X, Zhao W, Jia H T, Ding Y K, Zheng W G and He X T 2016 Matter and Radiation at Extremes 1 8
[4] Kawata S, Karino T and Ogoyski A I 2016 Matter and Radiation at Extremes 1 89
[5] Rochau G A, Bailey J E, Chandler G A, Cooper G, Dunham G S, Lake P W, Leeper R J, Lemke R W, Mehlhorn T A, Nikroo A, Peterson K J, Ruiz C L, Schroen D G, Slutz S A, Steinman D, Stygar W A and Varnum W 2007 Plasma Phys. Control. Fusion 49 B591
[6] Chittenden J P 2000 Phys. World 13 39
[7] Ding N, Zhang Y, Xiao D L, Wu J M, Dai Z H, Yin L, Gao Z M, Sun S K, Xue C, Ning C, Shu X J and Wang J G 2016 Matter and Radiation at Extremes 1 135
[8] Dittrich T R, Hurricane O A, Callahan D A, Dewald E L, Döppner T, Hinkel D E, Berzak Hopkins L F, Le Pape S, Ma T, Milovich J L, Moreno J C, Patel P K, Park H S, Remington B A, Salmonson J D and Kline J L 2014 Phys. Rev. Lett. 112 055002
[9] Kirkpatrick R C, Cremer C C, Madsen L C, Rogers H H and Cooper R S 1975 Nucl. Fusion 15 333
[10] Amendt P, Colvin J D, Tipton R E, Hinkel D E, Edwards M J, Landen O L, Ramshaw J D, Suter L J, Varnum W S and Watt R G 2002 Phys. Plasmas 9 2221
[11] Cobble J A and Sinars D B 2016 Los Alamos National Lab. Report LA-UR-16-24652
[12] Tian C, Yu M H, Shan L Q, Wu Y C, Zhang T K, Bi B, Zhang F, Zhang Q Q, Liu D X and Wang W W 2019 Nucl. Fusion 59 046012
[13] Montgomery D S, Daughton W S, Albright B J, Simakov A N, Wilson D C, Dodd E S, Kirkpatrick R C, Watt R G, Gunderson M A, Loomis E N, Merritt E C, Cardenas T, Amendt P, Milovich J L, Robey H F, Tipton R E and Rosen M D 2018 Phys. Plasmas 25 092706
[14] Molvig K, Schmitt M J, Albright B J, Dodd E S, Hoffman N M, McCall G H and Ramsey S D 2016 Phys. Rev. Lett. 116 255003
[15] Hu S X, Epstein R, Theobald W, Xu H, Huang H, Goncharov V N, Regan S P, McKenty P W, Betti R, Campbell E M and Montgomery D S 2019 Phys. Rev. E 100 063204
[16] Molvig K, Schmitt M J, Betti R, Campbell E M and McKenty P 2018 Phys. Plasmas 25 082708
[17] Scheiner B, Schmitt M J, Hsu S C, Schmidt D, Mance J, Wilde C, Polsin D N, Boehly T R, Marshall F J, Krasheninnikova N, Molvig K and Huang H B 2019 Phys. Plasmas 26 072707
[18] Keenan B D, Taitano W T and Molvig K 2020 Phys. Plasmas 27 042704
[19] Vesey R A, Herrmann M C, Lemke R W, Desjarlais M P, Cuneo M E, Stygar W A, Bennett G R, Campbell R B, Christenson P J, Mehlhorn T A, Porter J L and Slutz S A 2007 Phys. Plasmas 14 056302
[20] Hammer J H, Tabak M, Wilks S C, Lindl J D, Bailey D S, Rambo P W, Toor A and Zimmerman G B 1999 Phys. Plasmas 6 2129
[21] Cuneo M E, Vesey R A, Bennett G R, Sinars D B, Stygar W A, Waisman E M, Porter J L, Rambo P K, Smith I C, Lebedev S V, Chittenden J P, Bliss D E, Nash T J, Chandler G A, Afeyan B B, Yu E P, Campbell R B, Adams R G, Hanson D L, Mehlhorn T A and Matzen M K 2006 Plasma Phys. Control. Fusion 48 R1
[22] Sanford T W L, Lemke R W, Mock R C, Chandler G A, Leeper R J, Ruiz C L, Peterson D L, Chrien R E, Idzorek G C, Watt R G and Chittenden J P 2002 Phys. Plasmas 9 3573
[23] Peng X J and Wang Z 2014 High Power Laser Part. Beams 26 090201
[24] Stygar W A, Awe T J, Bailey J E, Bennett N L, Breden E W, Campbell E M, Clark R E, Cooper R A, Cuneo M E, Ennis J B, Fehl D L, Genoni T C, Gomez M R, Greiser G W, Gruner F R, Herrmann M C, Hutsel B T, Jennings C A, Jobe D O, Jones B M, Jones M C, Jones P A, Knapp P F, Lash J S, LeChien K R, Leckbee J J, Leeper R J, Lewis S A, Long F W, Lucero D J, Madrid E A, Martin M R, Matzen M K, Mazarakis M G, McBride R D, McKee G R, Miller C L, Moore J K, Mostrom C B, Mulville T D, Peterson K J, Porter J L, Reisman D B, Rochau G A, Rochau G E, Rose D V, Rovang D C, Savage M E, Sceiford M E, Schmit P F, Schneider R F, Schwarz J, Sefkow A B, Sinars D B, Slutz S A, Spielman R B, Stoltzfus B S, Thoma C, Vesey R A, Wakeland P E, Welch D R, Wisher M L and Woodworth J R 2015 Phys. Rev. Spec. Top. Accel. Beams 18 110401
[25] Ramis R and Meyer-ter-Vehn J 2016 Comput. Phys. Commun. 203 226
[26] Wu F Y, Chu Y Y, Ye F, Li Z H, Yang J L, Ramis R, Zhen W, Qi J M, Zhou L and Liang C 2017 Acta Phys. Sin. 66 215201 (in Chinese)
[27] Wu F Y, Chu Y Y, Ramis R, Li Z H, Ma Y Y, Yang J L, Wang Z, Ye F, Huang Z C, Qi J M, Zhou L, Liang C, Chen S J, Ge Z Y, Yang X H and Wang S W 2018 Matter and Radiation at Extremes 3 248
[28] Kemp A J and Meyer-ter-Vehn 1998 Nucl. Instrum. Methods A 415 674
[29] Eidmann K 1994 Laser and Particle Beams 12 223
[30] Ye F, Li Z H, Chen F X, Xue F B, Meng S J, Ning J M, Qin Y, Hu Q Y, Jiang S Q, Li L B, Chu Y Y, Yang J L, Xu R K and Xu Z P 2016 Phys. Plasmas 23 064502
[31] Lebedev S V, Beg F N, Bland S N, Chittenden J P, Dangor A E and Haines M G 2002 Phys. Plasmas 9 2293
[32] Slutz S A, Peterson K J, Vesey R A, Lemke R W, Bailey J E, Varnum W, Ruiz C L, Cooper G W, Chandler G A, Rochawu G A and Mehlhorn T A 2006 Phys. Plasmas 13 102701
[33] Xiao D L, Ding N, Ye F, Ning J M, Hu Q Y, Chen F X, Qin Y, Xu R K, Li Z H and Sun S K 2014 Phys. Plasmas 21 042704
[34] Chu Y Y, Wang Z, Qi J M, Wu F Y and Li Z H 2017 Nucl. Fusion 57 066019
[35] Lemke R W, Bailey J E, Chandler G A, Nash T J, Slutz S A and Mehlhorn T A 2005 Phys. Plasmas 12 012703
[36] Chittenden J P and Jennings C A 2008 Phys. Rev. Lett. 101 055005
[37] Peterson K J, Awe T J, Yu E P, Sinars D B, Field E S, Cuneo M E, Herrmann M C, Savage M, Schroen D, Tomlinson K and Nakhleh C 2014 Phys. Rev. Lett. 112 135002
[38] Xiao D L, Sun S K, Zhao Y K, Ding N, Wu J M, Dai Z H, Yin L, Zhang Y and Xue C 2015 Phys. Plasmas 22 052709
[39] Bailey J E, Chandler G A, Slutz S A, Bennett G R, Cooper G, Lash J S, Lazier S, Lemke R, Nash T J, Nielsen D S, Moore T C, Ruiz C L, Schroen D G, Smelser R, Torres J and Vesey R A 2002 Phys. Rev. Lett. 89 095004

Simulations on the multi-shell target ignition driven by radiation pulse in Z-pinch dynamic hohlraum

Simulations on the multi-shell target ignition driven by radiation pulse in Z-pinch dynamic hohlraum

RichHTML

PDF (PC)

赞

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

Metrics

本文评价

推荐阅读 0

[1]	Xiaoguang Wang(王小光), Guanqiong Wang(王冠琼), Shunkai Sun(孙顺凯), Delong Xiao(肖德龙), Ning Ding(丁宁), Chongyang Mao(毛重阳), and Xiaojian Shu(束小建). Scaling of rise time of drive current on development of magneto-Rayleigh-Taylor instabilities for single-shell Z-pinches[J]. 中国物理B, 2022, 31(2): 25203-025203.
[2]	王小光, 孙顺凯, 肖德龙, 王冠琼, 张扬, 周少彤, 任晓东, 徐强, 黄显宾, 丁宁, 束小建. Numerical study on magneto-Rayleigh-Taylor instabilities for thin liner implosions on the primary test stand facility[J]. 中国物理B, 2019, 28(3): 35201-035201.
[3]	王冠琼, 肖德龙, 但家坤, 张扬, 丁宁, 黄显宾, 王小光, 孙顺凯, 薛创, 束小建. Preliminary investigation on electrothermal instabilities in early phases of cylindrical foil implosions on primary test stand facility[J]. 中国物理B, 2019, 28(2): 25203-025203.
[4]	宁成, 张小强, 张扬, 孙顺凯, 薛创, 丰志兴, 李百文. Analytical studies on the evolution processes of rarefied deuterium plasma shell Z-pinch by PIC and MHD simulations[J]. 中国物理B, 2018, 27(2): 25207-025207.
[5]	杨学, 肖德龙, 丁宁, 刘杰. Magneto-Rayleigh–Taylor instability in compressible Z-pinch liner plasmas[J]. 中国物理B, 2017, 26(7): 75202-075202.
[6]	赵屾, 朱鑫磊, 石桓通, 邹晓兵, 王新新. End-on x-ray backlighting experiments for axial diagnostics of wire-array Z-pinch plasma on PPG-1[J]. 中国物理B, 2017, 26(1): 15206-015206.
[7]	赵屾, 薛创, 朱鑫磊, 张然, 罗海云, 邹晓兵, 王新新, 宁成, 丁宁, 束小建. Determining resistance of X-pinch plasma[J]. 中国物理B, 2013, 22(4): 45205-045205.
[8]	黄显宾,杨礼兵,李晶,周少彤,任晓东,张思群,但加坤,蔡红春,段书超,陈光华,章征伟,欧阳凯,李军,张朝辉,周荣国,王贵林. Radiation characteristics and implosion dynamics of tungsten wire array Z-pinches on the YANG accelerator[J]. 中国物理B, 2012, 21(5): 55206-055206.
[9]	叶凡, 李正宏, 秦义, 蒋树庆, 薛飞彪, 杨建伦, 徐荣昆, 金永杰. Spatially-resolved spectroscopic diagnosing of aluminum wire array Z-pinch plasmas on QiangGuang-I facility[J]. 中国物理B, 2010, 19(7): 75204-075204.
[10]	赵彤, 邹晓兵, 张然, 王新新. X-ray backlighting of two-wire Z-pinch plasma using X-pinch[J]. 中国物理B, 2010, 19(7): 75205-075205.
[11]	张扬, 丁宁. Stability analysis of viscous Z-pinch plasma with a sheared axial flow[J]. 中国物理B, 2008, 17(8): 2994-3002.
[12]	章法强, 李正宏, 许泽平, 徐荣昆, 杨建伦, 郭存, 夏广新, 陈进川, 宋凤军, 宁家敏, 王真, 薛飞彪, 李林波, 秦义, 应纯同, 刘广均. X-ray observations of tungsten wire array Z-pinch implosions on QiangGuang-1 facility[J]. 中国物理B, 2006, 15(9): 2058-2064.
[13]	段耀勇, 郭永辉, 王文生, 邱爱慈. Effects of drive current rise-time and initial load density distribution on Z-pinch characteristics[J]. 中国物理B, 2005, 14(9): 1856-1861.
[14]	徐荣昆, 李正宏, 杨建伦, 许泽平, 丁宁, 郭存, 蒋世伦, 宁佳敏, 夏广新, 李林波, 宋风军, 陈进川. Study of tungsten wire array Z-pinch implosion on Qiang-Guang I facility[J]. 中国物理B, 2005, 14(8): 1613-1617.
[15]	曾正中, 邱爱慈. Numerical study of the scaling of the maximum kinetic energy per unit length for imploding Z-pinch liner[J]. 中国物理B, 2004, 13(2): 201-204.