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Suggested Citation:"References." National Research Council. 2013. Assessment of Inertial Confinement Fusion Targets. Washington, DC: The National Academies Press. doi: 10.17226/18288.
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References

Barnard, J.J., R.O. Bangerter, E. Henestroza, I.D. Kaganovich, B.G. Logan, W.R. Meier, D.V. Rose, P. Santhanam, W.M. Sharp, D.R. Welch, and S.S. Yu. 2005. A final focus model for heavy-ion fusion driver codes. Nuclear Instruments and Methods in Physics Research A 544:243-254.

Beaudoin, G., P. Haljan, M. Paetkau, and J.R. Beamish. 1996. Freezing of molecular hydrogen and its isotopes in porous vycor glass. Journal of Low-Temperature Physics 105(1-2):113-131.

Bei, Z., T.B. Jones, and D.R. Harding. 2010. Electric field centering of double-emulsion droplets suspended in a density gradient. Soft Matter 6:2312-2320.

Belkov, S.A., S.G. Garanin, N.V. Jidkov, G.G. Kochemasov, and S.A. Suharev. 2010. The experimental studies conducted on the laser facilities of RFNC-VNIEFF: A review of the recent results. XXXVII Zvenigorod International Conference on Plasma Physics and Controlled Fusion.

Betti, R., A.A. Solodov, J.A. Delettrez, and C. Zhou. 2006. Gain curves for direct-drive fast-ignition at densities around 300 g/cc. Physics of Plasmas 13:100703.

Betti, R., C.D. Zhou, K.S. Anderson, L.J. Perkins, W. Theobald, and A.A. Solodov. 2007. Shock ignition of thermonuclear fuel with high areal density. Physical Review Letters 98:155001.

Biener, J., D.D. Ho, C. Wild, E. Woerner, M.M. Biener, B.S. El-dasher, D.G. Hicks, J.H. Eggert, P.M. Celliers, G.W. Collins, N.E. Teslich Jr,, B.J. Kozioziemski, S.W. Haan, and A.V. Hamza. 2009. Diamond spheres for inertial confinement fusion. Nuclear Fusion 49:112001.

Bobeica, M. 2009. Ph.D. Thesis. University of Rochester.

Bobeica, M., D.R Harding, and R.Q. Gram. 2005. An experimental method for measuring the response of a target to the thermal environment of the fusion reaction chamber. Twenty-first IEEE/NPS Symposium on Fusion Engineering.

Bodner, S.E., D.G. Colombant, A.J. Schmitt, J.H. Gardner, R.H. Lehmberg, and S.P. Obenschain. 2002. Overview of new high gain target design for a laser fusion power plant. Fusion Engineering and Design 60:93.

Boehly, T.R., V.N. Goncharov, W. Seka, M.A. Barrios, P.M. Celliers, D.G. Hicks, G.W. Collins, S.X. Hu, J.A. Marozas, and D.D. Meyerhofer. 2011. Velocity and timing of multiple spherically converging shock waves in liquid deuterium. Physical Review Letters 106(19):195005.

Callahan, D.A., M.C. Herrmann, and M. Tabak. 2002. Progress in heavy ion target capsule and hohlraum design. Laser and Particle Beams 20(3):405-410.

Suggested Citation:"References." National Research Council. 2013. Assessment of Inertial Confinement Fusion Targets. Washington, DC: The National Academies Press. doi: 10.17226/18288.
×

Carlson, L., M. Tillack, T. Lorentz, J. Spalding, N. Alexander, G. Flint, D Goodin, and R. Petzoldt. 2007. Target tracking and engagement for inertial fusion energy—A tabletop demonstration. Fusion Science and Technology 52(3):478.

Cho, S.K., H. Moon, and C.J. Kim. 2003. Creating, transporting, cutting, and merging liquid droplets by electrowetting-based actuation for digital microfluidic circuits. Journal of Microelectromechanical Systems 12(1):70.

Cok, A.M., R.S. Craxton, and P.W. McKenty. 2008. Polar-drive designs for optimizing neutron yields on the National Ignition Facility. Physics of Plasmas 15:082705.

Colombant, D.G., A.J. Schmitt, S.P. Obenschain, S.T. Zalesak, A.L. Velikovich, J.W. Bates, D.E. Fyfe, J.H. Gardner, and W. Manheimer. 2007. Direct-drive laser target designs for sub-megajoule energies. Physics of Plasmas 14:056317.

Garanin, S.F., V.I. Mamyshev, and V.B. Yakubov. 2006. The MAGO system: Current status. IEEE Transactions on Plasma Science 34:2273-2278.

Gardner, J.H., A.J. Schmitt, J.P. Dahlburg, C.J. Pawley, S.E. Bodner, S.P. Obenschain, V. Serlin, and Y. Aglitskiy. 1998. Computational modeling of direct-drive fusion pellets and KrF-driven foil experiments. Physics of Plasmas 5:1935.

Goldston, R.J., and A. Glaser. 2011. Inertial confinement fusion energy R&D and nuclear proliferation: The need for direct and transparent review. Bulletin of the Atomic Scientists 67(3):59-66.

Goncharov, V.N., T.C. Sangster, T.R. Boehly, S.X. Hu, I.V. Igumenshchev, F.J. Marshall, R.L. McCrory, D.D. Meyerhofer, P.B. Radha, W. Seka, S. Skupsky, C. Stoeckl, D.T Casey, J.A. Frenje, and R.D. Petrasso. 2010. Demonstration of the highest deuterium-tritium areal density using multiple-picket cryogenic designs on OMEGA. Physical Review Letters 104:165001.

Jones, S.L., and F.N. von Hippel. 1998. The question of pure fusion explosions under the CTBT. Science & Global Security 7:129-150.

Karasik, M., J.L. Weaver, Y. Aglitskiy, T. Watari, Y. Arikawa, T. Sakaiya, J. Oh, A.L. Velikovich, S.T. Zalesak, J.W. Bates, S.P. Obenschain, A.J. Schmitt, M. Murakami, and H. Azechiet. 2010. Acceleration to high velocities and heating by impact using Nike KrF laser. Physics of Plasmas 17:056317.

Kirillov, G.A., G.G. Kochemasov, A.V. Bessarab, S.G. Garanin, L.S. Mkhitarian, V.M. Murugov, S.A. Sukharev and N.V. Zhidkov. 2000. Status of laser fusion research at VNIIEF. Laser and Particle Beams 18(2):219-228.

Kodama, R., H. Shiraga, K. Shigemori, Y. Toyama, S. Fujioka, H. Azechi, H. Fujita, H. Habara, T. Hall, Y. Izawa, T. Jitsuno, Y. Kitagawa, K.M. Krushelnick, K.L. Lancaster, K. Mima, K. Nagai, M. Nakai, H. Nishimura, T. Norimatsu, P.A. Norreys, S. Sakabe, K.A. Tanaka, A. Youssef, M. Zepf, and T. Yamanaka. 2002. Nuclear fusion: Fast heating scalable to laser fusion ignition. Nature 418:933.

Lindemuth, I.R., R.E. Reinovsky, R.E. Chrien, J.M. Christian, C.A. Ekdahl, J.H. Goforth, R.C. Haight, G. Idzorek, N.S. King, R.C. Kirkpatrick, R.E. Larson, G.L. Morgan, B.W. Olinger, H. Oona, P.T. Sheehey, J.S. Shlachter, R.C. Smith, L.R. Veeser, B.J. Warthen, S.M. Younger, V.K. Chernyshev, V.N. Mokhov, A.N. Demin, Y.N. Dolin, S.F. Garanin, V.A. Ivanov, V.P. Korchagin, O.D. Mikhailov, I.V. Morozov, S.V. Pak, E.S. Pavlovskii, N.Y. Seleznev, A.N. Skobelev, G.I. Volkov, and V.A. Yakubov. 1995. Target plasma formation for magnetic compression/magnetized target fusion (MAGO/MTF). Physical Review Letters 75(10):1953-1956.

Liu, C.S., and M.N. Rosenbluth. 1976. Parametric decay of electromagnetic waves into two plasmons and its consequences. Physics of Fluids 19(7):967-971.

Marozas, J.A., J.D. Zuegel, and T.J.B. Collins. 2010. Smoothing by spectral dispersion (SSD) for multiple-picket pulses on OMEGA and the NIF. Bulletin of the American Physical Society 55:294.

Massard, T. 2010. ICF in France, status and perspective. Fusion Power Associates 31st Annual Meeting and Symposium, Washington, D.C., December 1-2.

Meserve, R.A. 2011. Nuclear energy and climate change. Nuclear Plant Journal 29(3):24.

Meyerhofer, D.D. 2001. Direct drive ignition research. Presentation to the Campaign Review Meeting, Los Alamos, N.M., December 3-6.

Mostovych, A.N., D.G. Colombant, M. Karasik, J.P. Knauer, A.J. Schmitt, and J.L. Weaver. 2008. Enhanced direct-drive implosions with thin high-Z ablation layers. Physical Review Letters 100:075002.

Norimatsu, T., K. Nagai, T. Takeda, K. Mima, and T. Yamanaka. 2003. Update for the drag force on an injected pellet and target fabrication for inertial fusion. Fusion Science and Technology 43:339.

NRC (National Research Council). 1986. Review of the Department of Energy’s Inertial Confinement Fusion Program. Washington, D.C.: National Academy Press.

Suggested Citation:"References." National Research Council. 2013. Assessment of Inertial Confinement Fusion Targets. Washington, DC: The National Academies Press. doi: 10.17226/18288.
×

NRC. 1990. Review of the Department of Energy’s Inertial Confinement Fusion Program. Washington, D.C.: National Academy Press.

NRC. 1997. Review of the Department of Energy’s Inertial Confinement Fusion Program: The National Ignition Facility. Washington, D.C.: National Academy Press.

Obenschain, S.P., D.G. Colombant, M. Karasik, C.J. Pawley, V. Serlin, A.J. Schmitt, J.L. Weaver, J.H. Gardner, L. Phillips, Y. Aglitskiy, Y. Chan, J.P. Dahlburg, and M. Klapisch. 2002. Effects of thin high-Z layers on the hydrodynamics of laser-accelerated plastic targets. Physics of Plasmas 9:2234.

Paine, C., and M.G. McKinzie. 1998. Does the U.S. science-based Stockpile Stewardship Program pose a proliferation threat? Science and Global Security 7:151-193.

Pawley, C.J., S.E. Bodner, J.P. Dahlburg, S.P. Obenschain, A.J. Schmitt, J.D. Sethian, C.A. Sullivan, J.H. Gardner, Y. Aglitskiy, Y. Chan, and T. Lehecka. 1999. Observation of Rayleigh–Taylor growth to short wavelengths on Nike. Physics of Plasmas 6:565.

Perkins, L.J., R. Betti, K.N. LaFortune, and W.H. Williams. 2009. Shock ignition: A new approach to high gain inertial confinement fusion on the National Ignition Facility. Physcal Review Letters 103:045004.

Petzoldt, R.W., D.T. Goodin, A. Nikroo, E. Stephens, N. Siegel, N.B. Alexander, A.R. Raffray, T.K. Mau, M. Tillack, F. Najmabadi, S.I. Krasheninnikov, and R. Gallix. 2002. Direct drive target survival during injection in an inertial fusion energy power plant. Nuclear Fusion 42:1351.

Schmitt, A.J., J.W. Bates, S.P. Obenschain, S.T. Zalesak, D.E. Fyfe, and R. Betti. 2009. Direct drive fusion energy shock ignition designs for sub-MJ lasers. Fusion Science and Technology 56:377.

Seka, W., D.H. Edgell, J.F. Myatt, A.V. Maximov, and H.A. Baldis. 2009. Two-plasmon-decay instability in direct-drive inertial confinement fusion experiments. Physics of Plasmas 16:52701.

Sethian, J.D., D.G. Colombant, J.L. Giuliani, R.H. Lehmberg, M.C. Myers, et al. 2010. The science and technologies for fusion energy with lasers and direct-drive targets. IEEE Transactions on Plasma Science 38(4):690-703.

Sharp, W.M., D.A. Callahan, M. Tabak, S.S. Yu, P.F. Peterson, D.V. Rose, and D.R. Welch. 2004. Chamber-transport simulation results for heavy-ion fusion drivers. Nuclear Fusion 44:S221.

Skupsky, S., J.A. Marozas, R.S. Craxton, R. Betti, T.J.B. Collins, J.A. Delettrez, V.N. Goncharov, P.W. McKenty, P.B. Radha, T.R. Boehly, J.P. Knauer, F.J. Marshall, D.R. Harding, J.D. Kilkenny, D.D. Meyerhofer, T.C. Sangster, and R.L. McCrory. 2004. Polar direct drive on the National Ignition Facility. Physics of Plasmas 11:2763.

Slutz, S.A., and R.A. Vesey. 2012. High-gain magnetized inertial fusion. Physical Review Letters 108(2):025003.

Sviatoslavsky, I.N., M.E. Sawan, R.R. Peterson, G.L. Kulcinski, J.J. MacFarlane, L.J. Wittenberg, H.Y. Khater, E. A. Mogahed, and S.C. Rutledge. 1992. A KrF laser driven inertial fusion reactor “SOMBRERO.” Fusion Technology 21:1470.

Theobald, W., R. Betti, C. Stoeckl, K.S. Anderson, J.A. Delettrez, V. Yu. Glebov, V.N. Goncharov, F.J. Marshall, D.N. Maywar, R.L. McCrory, D.D. Meyerhofer, P.B. Radha, T.C. Sangster, W. Seka, D. Shvarts, V.A. Smalyuk, A.A. Solodov, B. Yaakobi, C.D. Zhou, J.A. Frenje, C.K. Li, F.H. Séguin, R.D. Petrasso, and L.J. Perkins. 2008. Initial experiments on the shock-ignition inertial confinement fusion concept. Physics of Plasmas 15:056306.

Tillack, M., A.R. Raffray, F. Najmabadi, and L.C. Carlson. 2010. Target and chamber technologies for direct-drive laser-IFE. Final Report for the IAEA CRP: Pathways to Energy from Inertial Fusion (IFE)—An Integrated Approach. UCSD-CER-10-01. University of California, San Diego.

U.S. DOE (U.S. Department of Energy), Office of Declassification. 2001. Restricted Data Declassification Decisions, 1946 to the Present (RDD-7). Item V.C.1.g (declassification action 98-15). January 1.

U.S. DOE, Office of Arms Control and Nonproliferation. 1995. The National Ignition Facility (NIF) and the Issue of Nonproliferation: Final Study. December 19.

Utada, A.S., L.-Y. Chu, A. Fernandez-Nieves, D.R. Link, C. Holtze, and D.A. Weitz. 2007. Dripping, jetting, drops, and wetting: The magic of microfluidics. MRS Bulletin 32:702-708.

Velikhov, E. 2008. 80 Years of Fusion. AAAS 2008 Annual Meeting. Boston, Mass. February 14-18.

Wang, W., T.B. Jones, and D.R. Harding. 2011. On-chip double emulsion droplet assembly using electrowetting-on-dielectric and dielectrophoresis. Fusion Science and Technology 59:240-249.

Zalesak, S.T., A.J. Schmitt, A.L. Velikovich, and J.H. Gardner. 2005. Modeling fluid instabilities in inertial confinement fusion hydrodynamics codes. Physics of Plasmas 12:056311.

Zimmerman, G.G., D. Kershaw, D. Bailey, and J. Harte. 1978. LASNEX code for inertial confinement fusion (A). Journal of the Optical Society of America 68:549.

Suggested Citation:"References." National Research Council. 2013. Assessment of Inertial Confinement Fusion Targets. Washington, DC: The National Academies Press. doi: 10.17226/18288.
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Suggested Citation:"References." National Research Council. 2013. Assessment of Inertial Confinement Fusion Targets. Washington, DC: The National Academies Press. doi: 10.17226/18288.
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Suggested Citation:"References." National Research Council. 2013. Assessment of Inertial Confinement Fusion Targets. Washington, DC: The National Academies Press. doi: 10.17226/18288.
×
Page 88
Suggested Citation:"References." National Research Council. 2013. Assessment of Inertial Confinement Fusion Targets. Washington, DC: The National Academies Press. doi: 10.17226/18288.
×
Page 89
Suggested Citation:"References." National Research Council. 2013. Assessment of Inertial Confinement Fusion Targets. Washington, DC: The National Academies Press. doi: 10.17226/18288.
×
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In the fall of 2010, the Office of the U.S. Department of Energy's (DOE's) Secretary for Science asked for a National Research Council (NRC) committee to investigate the prospects for generating power using inertial confinement fusion (ICF) concepts, acknowledging that a key test of viability for this concept—ignition —could be demonstrated at the National Ignition Facility (NIF) at Lawrence Livermore National Laboratory (LLNL) in the relatively near term. The committee was asked to provide an unclassified report. However, DOE indicated that to fully assess this topic, the committee's deliberations would have to be informed by the results of some classified experiments and information, particularly in the area of ICF targets and nonproliferation. Thus, the Panel on the Assessment of Inertial Confinement Fusion Targets ("the panel") was assembled, composed of experts able to access the needed information. The panel was charged with advising the Committee on the Prospects for Inertial Confinement Fusion Energy Systems on these issues, both by internal discussion and by this unclassified report.

A Panel on Fusion Target Physics ("the panel") will serve as a technical resource to the Committee on Inertial Confinement Energy Systems ("the Committee") and will prepare a report that describes the R&D challenges to providing suitable targets, on the basis of parameters established and provided to the Panel by the Committee. The Panel on Fusion Target Physics will prepare a report that will assess the current performance of fusion targets associated with various ICF concepts in order to understand:

1. The spectrum output; 2. The illumination geometry; 3. The high-gain geometry; and 4. The robustness of the target design. The panel addressed the potential impacts of the use and development of current concepts for Inertial Fusion Energy on the proliferation of nuclear weapons information and technology, as appropriate. The Panel examined technology options, but does not provide recommendations specific to any currently operating or proposed ICF facility.

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