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1
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85037179405
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D. F. Gaitan, Ph.D. thesis, University of Mississippi, 1990 (unpublished)
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D. F. Gaitan, Ph.D. thesis, University of Mississippi, 1990 (unpublished).
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2
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0026664144
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D. F. Gaitan, L. A. Crum, C. C. Church, and R. A. Roy, J. Acoust. Soc. Am. 91, 3166 (1992).
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(1992)
J. Acoust. Soc. Am.
, vol.91
, pp. 3166
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Gaitan, D.F.1
Crum, L.A.2
Church, C.C.3
Roy, R.A.4
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4
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0000409663
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B. Gompf, R. Günther, G. Nick, R. Pecha, and W. Eisenmenger, Phys. Rev. Lett. 79, 1405 (1997).
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(1997)
Phys. Rev. Lett.
, vol.79
, pp. 1405
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Gompf, B.1
Günther, R.2
Nick, G.3
Pecha, R.4
Eisenmenger, W.5
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7
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85037196042
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Phys Rev. E (to be published)
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D. F. Gaitan and R. G. Holt, Phys Rev. E (to be published).
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Gaitan, D.F.1
Holt, R.G.2
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9
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0001583038
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B. P. Barber, C. C. Wu, R. Löfstedt, P. H. Roberts, and S. J. Putterman, Phys. Rev. Lett. 72, 1380 (1994).
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(1994)
Phys. Rev. Lett.
, vol.72
, pp. 1380
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Barber, B.P.1
Wu, C.C.2
Löfstedt, R.3
Roberts, P.H.4
Putterman, S.J.5
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10
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0028518611
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R. Hiller, K. Weninger, S. J. Putterman, and B. P. Barber, Science 266, 248 (1994).
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(1994)
Science
, vol.266
, pp. 248
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Hiller, R.1
Weninger, K.2
Putterman, S.J.3
Barber, B.P.4
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12
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0000255217
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D. Lohse, M. P. Brenner, T. F. Dupont, S. Hilgenfeldt, and B. Johnston, Phys. Rev. Lett. 78, 1359 (1997).
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(1997)
Phys. Rev. Lett.
, vol.78
, pp. 1359
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Lohse, D.1
Brenner, M.P.2
Dupont, T.F.3
Hilgenfeldt, S.4
Johnston, B.5
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17
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0032093396
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S. Hilgenfeldt, M. P. Brenner, S. Grossman, and D. Lohse, J. Fluid Mech. 365, 171 (1998).
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(1998)
J. Fluid Mech.
, vol.365
, pp. 171
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Hilgenfeldt, S.1
Brenner, M.P.2
Grossman, S.3
Lohse, D.4
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18
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85037237101
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Ya. B. Zel'dovich and Yu. P. Raizer, Physics of Shock Waves and High-Temperature Hydrodynamic Phenomena (Academic, New York, 1966), Chaps. I–III, and VII
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Ya. B. Zel'dovich and Yu. P. Raizer, Physics of Shock Waves and High-Temperature Hydrodynamic Phenomena (Academic, New York, 1966), Chaps. I–III, and VII.
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19
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0002373473
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contains a description of the LASNEX hydrocode
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G. B. Zimmerman and W. L. Kruer, Thermonuclear Fusion 2, 51 (1975); contains a description of the LASNEX hydrocode.
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(1975)
Thermonuclear Fusion
, vol.2
, pp. 51
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Zimmerman, G.B.1
Kruer, W.L.2
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20
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36849141514
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artificial viscosity is used for the numerical stability of shock waves and is not a real material viscosity
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J. von Neumann and R. D. Richtmyer, J. Appl. Phys. 21, 232 (1950); artificial viscosity is used for the numerical stability of shock waves and is not a real material viscosity.
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(1950)
J. Appl. Phys.
, vol.21
, pp. 232
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von Neumann, J.1
Richtmyer, R.D.2
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21
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85037253120
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(Formula presented) Handbook of Chemistry and Physics, 76th ed., edited by D. R. Lide (CRC Press, Boca Raton, FL, 1995), pp. 6–10 and 11; (Formula presented) °C. (Formula presented) N/m, and (Formula presented) °C
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(Formula presented) Handbook of Chemistry and Physics, 76th ed., edited by D. R. Lide (CRC Press, Boca Raton, FL, 1995), pp. 6–10 and 11; (Formula presented) °C. (Formula presented) N/m, and (Formula presented) °C.
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22
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85037179124
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(Formula presented) is obtained from the equation of state or from LASNEX 19
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(Formula presented) is obtained from the equation of state or from LASNEX 19.
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27
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0040955040
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B. P. Barber, R. A. Hiller, R. Löfstedt, S. J. Putterman, and K. R. Weninger, Phys. Rep. 28, 65 (1997).
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(1997)
Phys. Rep.
, vol.28
, pp. 65
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Barber, B.P.1
Hiller, R.A.2
Löfstedt, R.3
Putterman, S.J.4
Weninger, K.R.5
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28
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85037240656
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Handbook of Chemistry and Physics (Ref. 21), pp. 6–10, (Formula presented) (2.5, 20, and 33 °C)=0.0074, 0.023, and 0.05 bar; p. 6-251, (Formula presented)(20 °C)=5.37 mW/mK; p. 6-24, (Formula presented) (2.5, 20, and 33 °C)=16.6, 17.2, and 18.2 mW/mK; p. 6-10, (Formula presented)(2.5, 20, and 33 °C)=566, 598, and 620 mW/mK
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Handbook of Chemistry and Physics (Ref. 21), pp. 6–10, (Formula presented) (2.5, 20, and 33 °C)=0.0074, 0.023, and 0.05 bar; p. 6-251, (Formula presented)(20 °C)=5.37 mW/mK; p. 6-24, (Formula presented) (2.5, 20, and 33 °C)=16.6, 17.2, and 18.2 mW/mK; p. 6-10, (Formula presented)(2.5, 20, and 33 °C)=566, 598, and 620 mW/mK.
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31
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85037252492
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The molar fraction of water vapor is computed by scaling the calculated fraction for the (Formula presented) μm and (Formula presented) °C ambient condition and normalizing arbitrarily to 40%. The percent of water vapor is equal to (Formula presented)
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The molar fraction of water vapor is computed by scaling the calculated fraction for the (Formula presented) μm and (Formula presented) °C ambient condition and normalizing arbitrarily to 40%. The percent of water vapor is equal to (Formula presented)
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32
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0000613858
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R. Pecha, B. Gompf, G. Nick, Z. Q. Wang, and W. Eisenmenger, Phys. Rev. Lett. 81, 717 (1998).
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(1998)
Phys. Rev. Lett.
, vol.81
, pp. 717
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Pecha, R.1
Gompf, B.2
Nick, G.3
Wang, Z.Q.4
Eisenmenger, W.5
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