Hydrodynamic Bibliography

Cris W. Barnes

Thu Apr 6 13:10:08 MDT 2000
LA-UR-00-1113

I have been generating a bibliography of references on hydrodynamic theory and experiment. While this database is specifically intended to work with LaTeX and BibTeX, it should be useful to anyone. I offer copies to those interested, with the hope that they will make suggestions for additions or reorganization of the list. My short descriptions of the papers are still very preliminary and are intended more as a mnemonic reminder of the contents of a paper than a true descriptor.

In generating any such bibliography, selection criteria for inclusion must be generated and followed.

• Peer-reviewed journal articles. Exceptions include:
  1. published conference proceedings, especially the International Workshops on Compressible Turbulent Mixing.
  2. some seminal technical reports (such as [Bell51] or [Miles66]) or even memos (such as [Fisher82a]) that, from common reference and use, are accepted as ``published.''
• The emphasis is on hydro of compressible (large Mach number) systems, in particular driven by radiation or by magnetic fields.
• Again, seminal work in ``fluid dynamics'' must be recognized and referenced, but my eventual intent is not to create a review bibliography of fluid hydro.
• For the present, I also include papers relevant to the ``applications'' of hydrodynamics to inertial confinement fusion (ICF), materials properties (EOS for example), and pulsed-power liner implosions.

This file hydro_biblio.tex and the database file itself hydro.bibmay be obtained via anonymous ftp on ftp.lanl.gov in the subdirectory /public/cbarnes/bib/ (that is, a Universal Resource Locator address of ftp://ftp.lanl.gov/public/cbarnes/bib/). For those of you who found this document via a paper copy, it is available on the Web at http://public.lanl.gov/cbarnes/bib/hydro_biblio/hydro_biblio.html using the LaTeX2html converter.

I express my thanks to K. Nolan Carter for considerable help in locating and copying many of these references. I also thank Dan Winske and Warren Hsing for providing their lists of hydrodynamic references which have been a source for this list.

Here is the list of references, grouped somewhat by subject:

• General [Rayleigh00] [Taylor50] [Layzer55] [Chandrasekhar61a] [Harlow71] [Sharp84a] [Woodward84] [Hoffman95] [Lindl95] (huge review of ICF physics), [Rosen99] (simple review of ICF physics)

• Theoretical ablation stabilization: [Shiau74] [Henderson74b] [Bodner74] [Brueckner74b] [Lindl75] [Catto78] [Book80] [Evans82] [Takabe83] [Manheimer84a] [Takabe85] [Kull86b] [Emery86] [Emery89b] [Munro88] (density gradient effect), [Kull89] [Dahlburg90] (3-D), [Gardner91], [Mikaelian92] [Bud'ko92] [Bychkov94] [Sanz94] [Betti94] [Dahlburg95] (more 3-D), [Wouchuk95] [Betti95] [Betti96a] [Goncharov96a] [Goncharov96b]

• Numerical simulations of R-T: [Harlow66] [Daly67] [Freeman77] (density scale length and deceleration), [McCrory77] [Baker80] [Emery82a], [Tryggvason88], [Kerr88], [Emery88] (direct drive targets), [Emery89a] (retraction of #Emery88##2#Emery88[Emery88]), [Munro89] (rippled shock front tests), [Gamaly90], [Tabak90] (LASNEX simulations of direct drive), [Mikaelian90b] (LASNEX simulations), [Sakagami90a] (pusher-fuel in stagnating cylinders), [Weber94] (detailed modeling of planar experiments)

• Theoretical nonlinear R-T: [Chang59] [Ott72] (exact solution for thin layer), [McCrory76] [McCrory81a] [Verdon82a] (nonlinear spike evolution in planar), [Emery82b] (K-H rollup), [Menikoff83] (potential theory and conformal maps), [Youngs84], [Kull86a] (Least-squares approximation vs Layzer's model), [Baker87] (bubble and spike acceleration), [Glimm88] (Sharp-Wheeler bubble merger), [Youngs89] (2-D mix model), [Haan89a] (nonlinear saturation), [Haan91] (mode coupling), [Ofer92] (2-D code and mode coupling), [Alon95] (bubble and spike growth), [Shvarts95] (nonliner multimode in 2 and 3D), [Hazak96] (nonlinear Lagrangian formalism), [Hasegawa96] (weakly nonlinear ablative R-T), [Ofer96] (strongly nonlinear mode coupling), [Mikaelian98] (analytic nonlinear bubble amplitude)

• Experimental Rayleigh-Taylor: [Lewis50] [Ratafia73] [Barnes74] (HE-driven elastic-plastic effects), [Kilkenny80] (first use of laser?), [Sweeney81] (e-beam driven cylinders), [Cole82] (first sucessful use of laser?), [Whitlock84], [Grun84] (first face-on radiography, ablative stabilization), [Read84] (Rocket Rig and turbulent mixing), [Wark86] (direct-drive hemispheres), [Grun87] (effect of ISI), [Nishimura88] (corrugated spheres), [Jacobs88b] (3-D in water), [Desselberger90] [Delettrez90] (spectroscopic tracers and mix), [Kilkenny90] [Remington91], [Remington92] (large growth of planar foils), [Glendinning92], [Bradley92] (burnthrough and neutron yields from imprint growth), [Desselberger93] (smoothed laser beams), [Remington93a] [Remington94] (multimode), [Dittrich94] (pusher-fuel mix), [Remington95a] [Budil96a], [Dimonte96] (turbulent mixing with variable acceleration in LEM), [Azechi97a], [Hsing97a] [Hsing97b] (convergent cylinders), [Shigemori97] (direct-drive foils without imprint), [Taylor97] (saturation by mass ablation of laser imprint), [Schneider98] (laser sheet in LEM), [Weir98] (incompressible convergent gelatin cylinders), [Tubbs99a,Tubbs99b] (direct drive cylinders)

• Other R-T: [LeLevier55] (effect of density gradient), [Mitchner64] (basic theory with compressible fluids), [Miles66] (R-T of flat plate with material strength), [Menikoff77,Menikoff78] (linear growth and viscosity), [Scannapieco81] (acoustic and Lamb modes as well), [Hattori86] (deceleration in sphere), [Sakagami90a] (numerical deceleration in cylinder), [Mikaelian90a] (stratified spherical shells), [Fews93] (alpha-particle radiography), [Velikovich95] (effects on m=0 mode from rotation), [Velikovich96b] (Tailored density profiles in z-pinch), [Mikaelian96] (analytic theory including viscosity and surface tension), [Ruden97] (Material strength in quasi-spherical implosion), [Winske97] (Magnetized with variable gravity), [Abarzhi98] (stable steady flows)

• Experimental Mix: [Peyser95] (Nova shock tube), [Keane95] (x-ray spectroscopy), [Schneider98] (laser sheet in LEM), [Dunne00] (laser-driven experiments)

• Material strength: [Miles66] (R-T of flat plate with material strength), [Barnes74] (HE-driven elastic-plastic effects), [Steinberg80] (material strength model), [Swegle85] (stress vs strain), [Mikaelian96] (analytic theory including viscosity and surface tension), [Ruden97] (Material strength in quasi-spherical implosion), [Dimonte98] (``Yogurt'' experiment in LEM)

• ``Bell-Plesset'' or accelerationless growth: [Bell51] (compressible, Atwood number=1), [Plesset54a] (incompressible, spherical), [Birkhoff54], [Birkhoff56], [Plesset56a], [Fisher82a] (more general) [Gupta86] [Mikaelian87] [Gupta87] [Chapyak97]

• Three-dimensional: [Manheimer84b] (thin layer calculation), [Jacobs88a] (weakly non-linear incompressible), [Jacobs88b] (3-D experiment in water), [Dahlburg90] (ablative R-T), [Sakagami90b] (pusher-fuel contact surface in sphere), [Town91] (same as Sakagami90b but different result), [Yabe91] (compare R-T and K-H), [Youngs91] (R-T and mixing), [Youngs92] (3-D simulation constructing 2-D turbulence model), [Dahlburg93] (single-mode ablative), [Town94] (deceleration), [Marinak95] (experiment), [Marinak96] (applied to capsule implosions)

• Richtmyer-Meshkov: [Richtmyer60] [Meshkov69] [Meyer72] (2-D Lagrangian simulations), [Andronov76] (experiment and modeling), [Mikaelian85] (stratified layers), [Hammel93] (radiation-driven shock), [Dimonte93] (experiment), [Yang94] (analytic reflected rarefaction), [Brouillette94] (shock tube experiment with finite density gradient), [Peyser95] (Nova shock tube), [Velikovich96a] (nonlinear analytic), [Zhang96] (nonlinear analytic and comparison to Benjamin [experiment] and Grove [simulation]), [Wouchuk96] (analytic linear theory of rippled shocks), [Jourdan97] (Mach 3 shock tube and turbulent mixing), [Zhang97] (2-D analytic compressible theory), [Rightley97] (low-Mach shock tube), [Kane99] (in supernovae)

• Shocks: [Freeman55] (linear stability of planar shocks), [Freeman57] (same but with disturbances on walls), [Kessel74] (laser-driven shock waves in solid hydrogen), [Veeser78,Trainor79] (laser-driven shocks in aluminum), [Gardner82] (stability of imploding shocks), [Woodward84] (review article on simulations), [Watanabe92] (cylindrical shock tube experiment in air), [Hammel93] (radiography at 56 Mbar), [Cauble93] (0.75 Gbar), [Hammel94] (more radiography in plastics), [Baumung94,Baumung96] (KALIF light ion facility and shock physics), [Al'tshuler96] (Soviet explosive devices), [Endo95] (laser irradiated rippled shock), [Ishizaki96] (analytic nonuniform shock), [Evans96] (shocks in spherical van der Waals gas), [DaSilva97] (Deuterium EOS up to 2 Mbar), [Ishizaki97] (Rippled shock driven by nonuniform laser ablation), [Drake98] (flowing plasma ejecta driving shocks in foam) [Goldman99] (shock structuring by joints) [Goldman00] (inhomogeneities in targets)

• Kelvin-Helmholtz: [Chandrasekhar61b] (overview), [Plesset64] (effects of compressibility), [Ratafia73] (observation of?), [Emery82a] (numerical simulation), [Yabe91] (numerical comparison of R-T and K-H)

• Related ICF calculations: [Nuckolls72] (first ``ICF'' paper), [Henderson74a] (symmetry of spherical implosions), [Mason75] (efficiency of shells), [Bodner87] (direct drive), [Caruso94] (indirect drive and surface roughness calculations)

• Codes: [Zimmerman75a] (LASNEX), [Verdon82a] (DAISY?), [Woodward84] (review of methods for simulating shocks), [Larsen94] (HYADES), [Humphries98] (CRUNCH)

• ICF Implosions: [Emmett74] (Scientific American article about generic laser fusion), [Brueckner74a] (review of direct drive), [Fraley74] (thermonuclear burn), [Gamalii75] (secondary neutrons), [Kidder76] (theory of homogeneous isentropic compression and ICF), [Yaakobi80] (high density ZETA results), [Campbell80] ( by silicon activation), [Bodner81] (summary of direct drive), [Meyer-ter-Vehn82] (gain curves), [Skupsky81,Kacenjar82,Kacenjar84] ( by knockons), [Craxton86] (Scientific American article about direct drive), [Hauer86] (absorption-spectroscopy diagnosis), [Azechi86] ( using secondary nuclear fusion reactions), [Azechi87] (fuel-pusher mixing), [Henshaw87] (application of non-linear R-T), [McCrory88,Marshall89,McCrory90] (cryogenic implosions), [Campbell91] (overview of Nova program circa 1991), [Cable94], [Fews94] (alpha-particle imaging), [Delettrez94] (burnthrough experiments), [Lindl95] (review), [Bodner95,Lindl96a,Lindl96b] (criticism and response of indirect drive and NIF), [Roberts96] (theory of stability of spherical implosion), [Woolsey97] (spectroscopic measurements of pressure), [Wilson98] (beryllium capsule design), [Tahir98] (advanced fuels), [Rosen99] (simple review of ICF physics)

• ICF thermal conduction [Malone75] (electron conduction flux limit), [Gardner81] (wavelength scaling)

• Equation of State [Feynman49] (Fermi-Thomas model at high pressure), [Saumon91] (hydrogen: pressure dissociation), [Saumon92] (hydrogen: pressure ionization), [Saumon95] (astrophysical), [Weir96,Besson97,Nellis97] (Metallization of hydrogen?), [DaSilva97] (Deuterium EOS up to 2 Mbar), [Cauble98] (low-Z in 10--40 Mbar)

• Magnetized and pinches [Roberts62] (finite Larmor radius), [Harris62], [Hussey80] (MHD instabilities in liners), [Roderick83] (2-D theoretical models), [Roderick86] (effect of magnetic field diffusion), [Huba87] [Huba89] (Larmor radius effects), [Hussey95] (heuristic model for choosing wavelengths and amplitudes), [Peterson96] (2-D modeling of Pegasus), [Hammer96] (2-D modeling of SATURN), [Winske96] (hybrid simulations in slab), [Winske97] (Magnetized with variable gravity)

• Other (plasma physics related hydro effects or hydro problems of possible interest) [Crow75] (expansion of plasma into vacuum), [Belmonte98] (flutter and tumble from gravity and lift)

• References
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