Theoretical investigations on x-ray transport in radiation transport experiments on the Shenguang-III prototype laser facility

Guangwei Meng; Jun She; Tianming Song; Jiamin Yang; Min Wang

doi:10.1063/5.0043745

[1] O. L.Landen, O. A.Hurricane, L. F.Berzak Hopkins, D. S.Clark, H. F.Robey, L.Masse, F.Albert, D. T.Casey, N.Izumi, A.Nikroo, A. L.Kritcher, D. P.Turnbull, H.-S.Park, T.D?ppner, O. S.Jones, D. D.Ho, V. A.Smalyuk, C. R.Weber, S.LePape, D. E.Hinkel, C. A.Thomas, M.Stadermann, G. N.Hall, S. F.Khan, M.Hohenberger, W. W.Hsing, J. L.Peterson, R. P. J.Town, N. B.Meezan, L. J.Suter, D. K.Bradley, S. W.Haan, E. L.Dewald, J. L.Milovich, J. L.Kline, L.Divol, M. J.Edwards, T. R.Dittrich, J. D.Salmonson, B. K.Spears, A. G.MacPhee, J. S.Ross, J. E.Field, T.Ma, P. K.Patel, A.Pak, B. A.Hammel, D. A.Callahan, P. A.Amendt, R.Tommasini, A. J.MacKinnon. Indirect drive ignition at the National Ignition Facility. Plasma Phys. Controlled Fusion, 59, 014021(2017).

[2] R. E.Marshak. Effect of radiation on shock wave behavior. Phys. Fluids, 1, 24(1958).

[3] P.Amendt, O. L.Landen, L. J.Suter, S. W.Haan, S. H.Glenzer, R. L.Berger, J. D.Lindl, S. G.Glendinning, R. L.Kauffman. The physics basis for ignition using indirect-drive targets on the National Ignition Facility. Phys. Plasmas, 11, 339(2004).

[4] A. B. R.Cooper, J. F.Hund, V.Smalyuk, R. E.Marrs, S. A.MacLaren, B. R.Maddox, K.Lu, C. A.Back, R.Seugling, M. E.Foord, A. S.Moore, J. D.Sain, M. J.May, P.Graham, M. B.Schneider, W. W.Hsing, K.Dodson, P. E.Young, J. M.Foster. Streaked radiography of an irradiated foam sample on the National Ignition Facility. Phys. Plasmas, 20, 033301(2013).

[5] A. S.Moore, P.Graham, M.May, J.Satcher, J.Hund, J.Foster, B.Young, A. B. R.Cooper, C. A.Back, J.Klingmann, A. J.Comley, K.Lu, J.Sain, K.Baker, S.MacLaren, K.Widmann, M. B.Schneider, R.Marrs, G.Glendinning, W. W.Hsing, J.Castor, R.Seugling, P.Young. Radiation transport and energetics of laser-driven half-hohlraums at the National Ignition Facility. Phys. Plasmas, 21, 063303(2014).

[6] D.Mihalas, B. W.Mihalas. Foundations of Radiation Hydrodynamics(1966).

[7] G. C.Pomraning. The Equations of Radiation Hydrodynamics(1973).

[8] Y. B.Zeldovich, Y. P.Raizer. Physics of Shock Waves and High Temperature Hydrodynamics Phenomena(1984).

[9] J.Li, J.Li, G.Meng. Reversal of Hugoniot Iocus for strong shocks due to radiation. Phys. Plasmas, 18, 042301(2011).

[10] J. O.Kane, M. W.Pound, H.Takabe, B. A.Remington, D. D.Ryutov, A.Mizuta. Formation of pillars at the boundaries between H II regions and molecular clouds. Astrophys. J., 647, 1151(2006).

[11] J. H.Hammer, M. D.Rosen. A consistent approach to solving the radiation diffusion equation. Phys. Plasmas, 10, 1829(2003).

[12] G.Meng, J.Yang, S.Zou, M.Wang, J.Li, W.Zhang, T.Zhu. A simple method to verify the opacity and equation of state of high-Z plasmas. Phys. Plasmas, 20, 092704(2013).

[13] J. H.Hammer, O. A.Hurricane. Bent Marshak waves. Phys. Plasmas, 13, 113303(2006).

[14] X.Wang, J.Wang, W.Zhang, G.Meng, J.Li. Generation of a sharp density increase in radiation transport between high-Z and low-Z plasmas. Matter Radiat. Extremes, 1, 249(2016).

[15] T.Shussman, S. I.Heizler. Full self-similar solutions of the subsonic radiative heat equations. Phys. Plasmas, 22, 082109(2015).

[16] C. A.Back, J. H.Hammer, B. F.Lasinski, O. L.Landen, P. W.Rambo, L. J.Suter, M. D.Rosen, W. W.Hsing, R. E.Turner, J. D.Bauer. Diffusive, supersonic x-ray transport in radiatively heated foam cylinders. Phys. Plasmas, 7, 2126(2000).

[17] J. L.Kline, K.Mussack, J. M.Taccetti, D. W.Schmidt, R. M.Stevenson, S.Allan, A. J.Comley, N. E.Lanier, N.Bazin, L.Reed, J.Cowan, K.Flippo, W.Garbett, J.Benstead, K.Obrey, C.Bentley, J.Workman, C.Hamilton, T. M.Guymer, J.Morton, A. S.Moore. Quantifying equation-of-state and opacity errors using integrated supersonic diffusive radiation flow experiments on the National Ignition Facility. Phys. Plasmas, 22, 043303(2015).

[18] T.Zhu, W.Shang, G.Xiong, W.Zhang, Y.Zhao, T.Song, J.Yang, J.Zhang. Study of x-ray radiant characteristics and thermal radiation redistribution in CH foam filling cylindrical cavities. Phys. Plasmas, 18, 042705(2011).

[19] T.Zhu, J.Zhang, R.Yi, J.Li, Z.Hu, Y.Ding, Y.Ding, S.Liu, G.Meng, J.Yang, Y.Xu, X.He. Experimental study of the hydrodynamic trajectory of an x-ray-heated gold plasmas. Phys. Plasmas, 17, 062702(2010).

[20] L.Barringer, O.Willi, C.Vickers, D.Hoarty. Study of super- and subsonic ionization fronts in low-density, soft X-ray-irradiated foam targets. Astrophys. J., Suppl. Ser., 127, 527(2000).

[21] C.Wu(2008).

[22] C.Huang, X.Luo(2015).

[23] L.Guo, X.Zhao, X.Jiang, J.Yang, H.Du, S.Li, R.Yi, T.Song, S.Jiang, Z.Li, J.Zheng, Y.Ding, S.Liu, Y.Liu, T.Huang. A novel flat-response x-ray detector in the photon energy range of 0.1–4 keV. Rev. Sci. Instrum., 81, 073504(2010).

[24] X.Jiang, S.Li, L.Guo, T.Song, R.Yi, H.Zhang, Y.Ding, Z.Li, Z.Wang, S.Jiang, D.Yang. The influence of laser clipped by the laser entrance hole on hohlraum radiation measurement on Shenguang-III prototype. Rev. Sci. Instrum., 85, 033504(2014).

[25] T.Feng. A numerical method for solving radiation transport equation on Lagrangian mesh. Chin. J. Comput. Phys., 21, 427(2004).

[26] Y.Rong, L.Jinghong, H.Xudeng. A two-dimensional cylindric symmetric radiative transfer benchmark model and code tests. Chin. J. Comput. Phys., 27, 533(2010).

[27] S. J.Davidson, F. J. D.Serduke, C. A.Iglesias, E.Minguez. WorkOp-IV summary: Lessons from iron opacities. J. Quant. Spectrosc. Radiat. Transfer, 65, 527(2000).

[28] R. M.More, G. B.Zimmerman, D. A.Young, K. H.Warren. A new quotidian equation of state (QEOS) for hot dens matter. Phys. Fluids, 31, 3059(1988).

[29] The Compilation Group of Handbook of Mathematics. Handbook of Mathematics, 865-866(1979).