An efficient method of fuel ice formation in moving free-standing ICF/IFE targets

Journal of Physics D: Applied Physics

Volumn 37, Issue 8, 2004, Pages 1163-1178

  Aleksandrova, I V ^a   Bazdenkov, S V ^a   Chtcherbakov, V I ^a   Gromov, A I ^a   Koresheva, E R ^a   Koshelev, E A ^a   Osipov, I E ^a   Yaguzinskiy, L S ^b  

^a LEBEDEV PHYSICAL INSTITUTE   (Russian Federation)

^b MOSCOW STATE UNIVERSITY   (Russian Federation)

Author keywords

[No Author keywords available]

Indexed keywords

DEFORMATION; ELASTICITY; ENVIRONMENTAL IMPACT; FUELS; INERTIAL CONFINEMENT FUSION; SURFACE TREATMENT;

CONCENTRICITY; FUEL ICE FORMATION; SPHERICITY; UNIFORMITY;

CRYOGENICS;

EID: 2342519546     PISSN: 00223727     EISSN: None     Source Type: Journal    
DOI: 10.1088/0022-3727/37/8/004     Document Type: Article

References (32)

1. Monsler M J, Merkulèv Y A and Norimatsu T 1995 Target fabrication and injection Energy From Inertial Fusion (Vienna; IAEA)
2. Aleksandrova IV, Koresheva E R, Krokhin O N and Osipov I E 1999 Statistical investigations of cryogenic target formation and future trends of development J. Moscow Phys. Soc. 9 311-24
3. Aleksandrova I V, Koresheva E R and Osipov I E 1999 Free-standing targets for applications to ICF Laser Particle Beams 17 713-27
4. Sangster T C et al 2002 Direct-drive cryogenic target implosion performance on OMEGA LLE Rev. 93 1-10
5. Sater J et al 1999 Cryogenic DT-fuel layers formed in 1 mm spheres by beta-layering Fusion Technol 35 229
6. Aleksandrova I V et al 2001 Extension of free-standing target technologies on IFE requirements Inertial Fusion Science and Application ed K A Tanaka et al (Paris: Elsevier) p 762
7. Koresheva E R et al 2003 Progress in the extension of free-standing target technologies on IFE requirements Fusion Sci. Technol. 35 10
8. Aleksandrova I V et al 2000 Free-standing target system for ICF Fusion Technol. 38 166
9. Aleksandrova I V, Koresheva E R and Osipov I E 1996 Injection as a principle of the target transport among the basic units: fill system - layering module - target chamber Contribution to the 11th Target Fabrication Specialists' Meeting (Ocras Island, Washington, 8-12 September)
10. Aleksandrova I V, Bazdenkov S V and Chtcherbakov V I 2001 Rapid fuel layering inside moving free-standing ICF targets: physical model and simulation code development Proc. SPIE. 4424 197
11. Aleksandrova IV, Bazdenkov S V and Chtcherbakov V I 2002 Laser Particle Beams 20 13
12. Chtcherbakov V I, Bazdenkov S V and Aleksandrova I V 2002 Integrated FST-layering code for the optimization of fuel ice formation in moving ICF/IFE capsules Contribution to the 27th European Conf. on Laser Interaction with Matter (Moscow, Russia, 7-11 October 2002)
13. Aleksandrova I V, Koresheva E R and Osipov I E 1993 The changes in the morphology of frozen hydrogen izotope layers under the target heating J. Moscow Phys. Soc. 3 85-100
14. Aleksandrova IV, Koresheva E R and Osipov IE 1994 ICF cryotargets: science and technology J. Moscow Phys. Soc. 4 81-128
15. Aleksandrova I V, Koresheva E R, Osipov I E and Panina L V 1996 Cryotargets for modern ICF experiments Laser Particle Beams 6 539-51
16. Koresheva E R et al 2001 Cryogenic fuel layer, fuel core and method of its fabrication Patent of Russian Federation claim no 2001121680 (9 August 2001) USA Patent claim no 10/207,733 (10 October 2002)
17. Koresheva E R, Osipov I E, Timasheva T P and Yaguzinskiy L S 2002 A New Approach to form transparent solid layer of hydrogen inside a microshell: application to inertial confinement fusion J. Appl. Phys. D 35 825
18. Aleksandrova I V, Koresheva E R, Osipov I E, Golov V I and Chtcherbakov V I 1999 Microtomography data processing methods for cryogenic target characterization Laser Particle Beams 17 729-40
19. Aleksandrova I V, Belolipetskiy A A, Golov V I, Chtcherbakov V I, Makeyeva E V, Koresheva E R and Osipov I E 2000 Progress in the development of tomographic information processing methods for applications to ICF target characterization Fusion Technol. 38 190-205
20. Nikitenko A I and Tolokonnikov S M 2002 Characterization of hydrogen ice surface quality in ICF targets using backlit shadowgraphy Contribution to the 27th European Conf. on Laser Interaction with Matter (Moscow, Russia, 7-11 October 2002)
21. Aleksandrova I V, Bazdenkov S V and Chtcherbakov V I 2002 Inverse algorithm for tomographic analysis of backlit shadowgraphy for application to ICF targets diagnostics Contribution to the 27th European Conf. on Laser Interaction with Matter (Moscow, Russia, 7-11 October 2002)
22. Belolipetskiy A A, Aleksandrova I V and Pisarnitskaya E A 2002 On the possibility of laser target characterization on the base of a threshold algorithm Contribution to the 27th European Conf. on Laser Interaction with Matter (Moscow, Russia, 7-11 October 2002)
23. Osipov I E et al 2002 Upgrade of the free-standing target system: creation of tomograph facility for target characterization Contribution to the 27th European Conf. on Laser Interaction with Matter (Moscow, Russia, 7-11 October 2002)
24. Baranov G D, Osipov IE, Timofeev I D, Listratov V I, Koshelev E L and Koresheva E R 2003 Multi-functional target-positioning device for rapid tomographic data acquisition Contribution to the 3rd IFSA (Monterey, 7-12 September 2003)
25. Nakai S and Miley G N 1992 Physics of High Power Laser and Matter Interactions (Singapore: Word Scientific) p 87
26. Roder H M, Childs G E, McCarty R D and Angerhofer P E 1973 Survey of the properties of the hydrogen isotopes below their critical temperatures NBS Techn. Note # 641 US Department of Commerce (Colorado: Boulder)
27. Aleksandrova I V, Bazdenkov S V, Chtcherbakov V I, Koresheva E R and Osipov I E 2001 Rep-rated cryogenic solid layering using free-standing target system Contribution to the 2nd International Conf. on the Inertial Fusion Science and Applications (Kyoto, Japan, 9-14 September 2001)
28. Osipov I E, Koresheva E R and Baranov G D 1999 A ramp-filling procedure applied to filling polymer and glass shell with highly pressurized hydrogens J. Moscow Phys. Soc. 9 301-9
29. Aleksandrova I V and Belolipetskiy A A 1999 An efficient method for filling targets with a highly-pressurized gas fuel J. Moscow Phys. Soc. 9 325-37
30. Aleksandrova IV and Belolipetskiy A A 1999 Mathematical models for filling polymer shells with a real-gas fuel Laser Particle Beams 17 701-12
31. Kobayashi S, Norimatsu T, Nakai M, Tanaka K A, Tamanaka T and Nakai S 1991 Annealing of polystyrene microcapsules for inertial confinement fusion experiments J. Vac. Sci. Technol. A 9 150-3
32. Fagaly R L, Alexander N B, Bittner D N, Bourque R F, Kim H-J and Lindgren J R 1992 The cryogenic target delivery system for OMEGA Upgrade Contribution to the 39th National Symp. Am. Vac. Soc. (Chicago, 9-13 November 1992)