terry.bib

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@BOOK{cmake,
  title = {Mastering CMake 4th Edition},
  publisher = {Kitware, Inc.},
  year = {2008},
  author = {Martin, Ken and Hoffman, Bill},
  address = {USA},
  crossref = {sl},
  isbn = {1930934203, 9781930934207}
}

@ARTICLE{Ahlborn1984,
  author = {Ahlborn,Boye},
  title = {Comments on ?A simple model of ion beam heated ICF targets? by R.
	G. Evans},
  journal = {Laser and Particle Beams},
  year = {1984},
  volume = {2},
  pages = {121-121},
  number = {01},
  abstract = { ABSTRACT In a recent study R. G. Evans developed an analytic model
	for ICF targets heated by heavy ion beams in order to show the differences
	to laser beam heating. However, these differences are really not
	very pronounced. In fact, Evans' model should be directly applicable
	to describe exploding pusher foil targets. In addition, Evans' scaling
	law for the ablation pressure PA with target density ρ0 and
	particle beam intensity Ib,is identical to the scaling found for
	laser targets with tamped flow (Ahlborn, 1981). },
  doi = {10.1017/S0263034600000653},
  eprint = {http://journals.cambridge.org/article_S0263034600000653},
  file = {Ahlborn1984.pdf:Ahlborn1984.pdf:PDF},
  url = {http://dx.doi.org/10.1017/S0263034600000653}
}

@ARTICLE{Ahlborn1981,
  author = {B Ahlborn and M H Key},
  title = {Scaling laws for laser driven exploding pusher targets},
  journal = {Plasma Physics},
  year = {1981},
  volume = {23},
  pages = {435},
  number = {5},
  abstract = {An analytic model based on shock waves is used to describe the maximum
	density rho F , maximum temperature T F and minimum radius R F obtained
	in the laser driven implosion of a gas filled spherical shell target
	of shell thickness Delta T, shell radius R and initial gas density
	rho 1 . The scaling behaviour rho F approximately rho 1 2 5/, rho
	F R f approximately rho 1 3 5/R and T F approximately ( alpha E 0
	/M) rho 1 -2 5/, is obtained, where E 0 is the laser energy, M is
	the shell mass, and alpha is the hydrodynamically useful fraction
	of the laser energy. Instantaneous uniform heating of the shell is
	assumed in order to describe implosions of the 'exploding pusher'
	type.},
  file = {Ahlborn1981.pdf:Ahlborn1981.pdf:PDF},
  url = {http://stacks.iop.org/0032-1028/23/i=5/a=005}
}

@MISC{pytables,
  author = {Francesc Alted and Ivan Vilata and others},
  title = {{PyTables}: Hierarchical Datasets in {Python}},
  year = {2002--},
  url = {http://www.pytables.org/}
}

@ARTICLE{Aono1968,
  author = {Osamu Aono},
  title = {Various Expressions of the Kinetic Equation for a Plasma},
  journal = {The Physics of Fluids},
  year = {1968},
  volume = {11},
  pages = {341-345},
  owner = {mrterry},
  timestamp = {2009.04.14}
}

@ARTICLE{Aono1962,
  author = {Aono, Osamu},
  title = {Fluctuations in a Plasma II: The Numerical Factor of in the Coulomb
	Logarithm},
  journal = {Journal of the Physical Society of Japan},
  year = {1962},
  volume = {17},
  pages = {853-864},
  owner = {mrterry},
  timestamp = {2009.04.15}
}

@ARTICLE{Arista1985,
  author = {N R Arista},
  title = {Low-velocity stopping power of semidegenerate quantum plasmas},
  journal = {Journal of Physics C: Solid State Physics},
  year = {1985},
  volume = {18},
  pages = {5127-5134},
  number = {26},
  abstract = {The energy loss of a slow charged particle in a semidegenerate plasma
	is calculated using analytical approximations. Previous results obtained
	by various authors are compared with these calculations. An analytical
	expression describes the stopping power for low velocities, over
	a wide range of plasma densities and temperatures. The description
	applies from the cold limit of solid state plasmas to the hot and
	dilute extreme of Tokamak plasmas.},
  file = {Arista1985.pdf:Arista1985.pdf:PDF},
  owner = {mterry},
  timestamp = {2007.11.01},
  url = {http://stacks.iop.org/0022-3719/18/5127}
}

@ARTICLE{Arista1983,
  author = {N R Arista and W Brandt},
  title = {On the slowing down of charged particles in an electron gas: an extension
	to the Fermi-Teller formula},
  journal = {Journal of Physics C: Solid State Physics},
  year = {1983},
  volume = {16},
  pages = {L1217-L1220},
  number = {36},
  abstract = {An expression is obtained for the low-velocity stopping power of an
	electron plasma in thermal equilibrium, which applies for all degrees
	of plasma degeneracy. In the limit of high densities the result agrees
	with the Fermi-Teller approximation for a cold plasma, and with a
	previous approximation of Skupsky (1977) for all degeneracies. It
	gives better agreement with the Lindhard-Winther result (1964) at
	lower (metallic) densities for cold plasmas, and it also agrees with
	a previous result of Arista and Brandt (1981) in the opposite limit
	of dilute nondegenerate plasmas.},
  file = {Arista1983.pdf:Arista1983.pdf:PDF},
  owner = {mterry},
  timestamp = {2007.11.01},
  url = {http://stacks.iop.org/0022-3719/16/L1217}
}

@ARTICLE{Arista1981,
  author = {Arista, N\'estor R. and Brandt, Werner },
  title = {Energy loss and straggling of charged particles in plasmas of all
	degeneracies},
  journal = {Phys. Rev. A},
  year = {1981},
  volume = {23},
  pages = {1898--1905},
  number = {4},
  month = {Apr},
  doi = {10.1103/PhysRevA.23.1898},
  file = {Arista1981.pdf:Arista1981.pdf:PDF},
  numpages = {7},
  owner = {mterry},
  timestamp = {2007.11.01}
}

@BOOK{Atzeni2004,
  title = {The Physics of Inertial Fusion},
  publisher = {Oxford University Press Inc},
  year = {2004},
  author = {Stefano Atzeni and Meyer-ter-Vehn, J\"urgen},
  owner = {mrterry},
  timestamp = {2008.02.28}
}

@ARTICLE{Atzeni2011,
  author = {S Atzeni and A Schiavi and A Marocchino},
  title = {Studies on the robustness of shock-ignited laser fusion targets},
  journal = {Plasma Physics and Controlled Fusion},
  year = {2011},
  volume = {53},
  pages = {035010},
  number = {3},
  abstract = {Several aspects of the sensitivity of a shock-ignited inertial fusion
	target to variation of parameters and errors or imperfections are
	studied by means of one-dimensional and two-dimensional numerical
	simulations. The study refers to a simple all-DT target, initially
	proposed for fast ignition (Atzeni et al 2007 Phys. Plasmas 7 052702)
	and subsequently shown to be also suitable for shock ignition (Ribeyre
	et al 2009 Plasma Phys. Control. Fusion [/0741-3335/51] 51 015013
	). It is shown that the growth of both Richtmyer–Meshkov and Rayleigh–Taylor
	instability (RTI) at the ablation front is reduced by laser pulses
	with an adiabat-shaping picket. An operating window for the parameters
	of the ignition laser spike is described; the threshold power depends
	on beam focusing and synchronization with the compression pulse.
	The time window for spike launch widens with beam power, while the
	minimum spike energy is independent of spike power. A large parametric
	scan indicates good tolerance (at the level of a few percent) to
	target mass and laser power errors. 2D simulations indicate that
	the strong igniting shock wave plays an important role in reducing
	deceleration-phase RTI growth. Instead, the high hot-spot convergence
	ratio (ratio of initial target radius to hot-spot radius at ignition)
	makes ignition highly sensitive to target mispositioning.},
  url = {http://stacks.iop.org/0741-3335/53/i=3/a=035010}
}

@TECHREPORT{petsc-user-ref,
  author = {Satish Balay and Jed Brown and and Kris Buschelman and Victor Eijkhout
	and William D. Gropp and Dinesh Kaushik and Matthew G. Knepley and
	Lois Curfman McInnes and Barry F. Smith and Hong Zhang},
  title = {{PETS}c Users Manual},
  institution = {Argonne National Laboratory},
  year = {2011},
  number = {ANL-95/11 - Revision 3.2}
}

@ARTICLE{Baldwin1962,
  author = {David E. Baldwin},
  title = {Close Collisions in a Plasma},
  journal = {Physics of Fluids},
  year = {1962},
  volume = {5},
  pages = {1523-1530},
  number = {12},
  doi = {10.1063/1.1706561},
  file = {Baldwin1962.pdf:Baldwin1962.pdf:PDF},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PFL/5/1523/1}
}

@ARTICLE{Balescu1960,
  author = {R. Balescu},
  title = {Irreversible Processes in Ionized Gases},
  journal = {Physics of Fluids},
  year = {1960},
  volume = {3},
  pages = {52-63},
  number = {1},
  doi = {10.1063/1.1706002},
  file = {Balescu1960.pdf:Balescu1960.pdf:PDF},
  owner = {mrterry},
  publisher = {AIP},
  timestamp = {2008.03.28},
  url = {http://link.aip.org/link/?PFL/3/52/1}
}

@ARTICLE{Balescu1960a,
  author = {Balescu, R.},
  title = {Transport Equation of a Plasma},
  journal = {Rev. Mod. Phys.},
  year = {1960},
  volume = {32},
  pages = {719--721},
  number = {4},
  month = {Oct},
  doi = {10.1103/RevModPhys.32.719},
  file = {Balescu1960a.pdf:Balescu1960a.pdf:PDF},
  numpages = {2},
  owner = {mrterry},
  publisher = {American Physical Society},
  timestamp = {2008.03.28}
}

@ARTICLE{Bangerter1982,
  author = {R. O. Bangerter and J. W. -K. Mark and A. R. Thiessen},
  title = {Heavy ion inertial fusion: Initial survey of target gain versus ion-beam
	parameters},
  journal = {Physics Letters A},
  year = {1982},
  volume = {88},
  pages = {225 - 227},
  number = {5},
  doi = {DOI: 10.1016/0375-9601(82)90233-X},
  file = {:Bangerter1982.pdf:PDF},
  issn = {0375-9601},
  url = {http://www.sciencedirect.com/science/article/B6TVM-46S5XVP-4HK/2/1c0b1f9694d7b3941b6b0cb8c977b43c}
}

@ARTICLE{Bangerter1977,
  author = {Bangerter, R O and Meeker, D. J.},
  title = {Charged Particle Fusion Targets},
  journal = {UCRL},
  year = {1977},
  volume = {79875},
  file = {:Bangerter1977.pdf:PDF},
  owner = {terry10},
  timestamp = {2011.04.29}
}

@ARTICLE{Bangerter1976,
  author = {Bangerter, R O and Meeker, D. J.},
  title = {Ion Beam Inertial Fusion Target Designs},
  journal = {UCRL},
  year = {1976},
  volume = {78474},
  file = {:Bangerter1976.pdf:PDF},
  owner = {terry10},
  timestamp = {2011.04.29}
}

@ARTICLE{Barletta1985,
  author = {Barletta,W. A. and Fawley,W. M. and Judd,D. L. and Mark,J. W-K. and
	Yu,S. S.},
  title = {Heavy ion inertial fusion: Interface between target gain, accelerator
	phase space and reactor beam transport revisited},
  journal = {Laser and Particle Beams},
  year = {1985},
  volume = {3},
  pages = {41-49},
  number = {01},
  abstract = { ABSTRACT Recently revised estimates of target gain have added additional
	optimistic inputs to the interface between targets, accelerators
	and fusion chamber beam transport. But it remains valid that neutralization
	of the beams in the fusion chamber is useful if ion charge state
	Z > 1 or if > 1 kA per beamlet is to be propagated. Some engineering
	and economic considerations favor higher currents. },
  doi = {10.1017/S0263034600001257},
  eprint = {http://journals.cambridge.org/article_S0263034600001257},
  url = {http://dx.doi.org/10.1017/S0263034600001257}
}

@ARTICLE{Basko1999,
  author = {M.M. Basko},
  title = {A 6 MJ spherical hohlraum target for heavy ion inertial fusion},
  journal = {Nuclear Fusion},
  year = {1999},
  volume = {39},
  pages = {1031},
  number = {8},
  abstract = {A new target option for energy applications of heavy ion inertial
	fusion is analysed. It has a spherical hohlraum and is irradiated
	by ion beams along the directions of the zeros of the fourth Legendre
	polynomial P 4 . The target performance is simulated with a 1-D three
	temperature hydrodynamics code and with a 2-D view factor code. Its
	efficiency is shown to depend crucially on the structure of the hohlraum
	wall, which, simultaneously, plays the role of the X¬?ray converter.
	For an optimized pulse power profile, a 1-D energy gain of G = 78
	is calculated with an input energy of E dr = 6.1¬?MJ in the form
	of 5¬?GeV 209 Bi ions focused on the target sphere with an outer
	radius of R = 6.37¬?mm.},
  file = {:Basko1999.pdf:PDF},
  url = {http://stacks.iop.org/0029-5515/39/i=8/a=307}
}

@ARTICLE{Basko1993b,
  author = {M.M. Basko},
  title = {Symmetry of illumination and implosion of hotraum targets for heavy
	ion inertial fusion},
  journal = {Nuclear Fusion},
  year = {1993},
  volume = {33},
  pages = {615},
  number = {4},
  abstract = {The symmetry of implosion of the hotraum target that has been proposed
	by J. Meyer-ter-Vehn and the author is analysed in the case when
	the target is driven by a nonspherical ensemble of heavy ion beams.
	The ion beams, each with a final focus radius r bf ?â? R (R is the
	target radius), are all assumed to irradiate the target at the same
	angle ?± 0 and symmetrically with respect to the equatorial plane.
	Separate one dimensional (1-D) simulations for the pole and equator
	target sectors indicate that the l = 2 mode in the asymmetry of fuel
	implosion vanishes for ?± 0 ?âà 36¬?. The l = 4 mode can also be
	eliminated by adjusting the ion current profile across each beam.
	It is conjectured that the higher asymmetry modes with l ?â? 6 will
	be smoothed out by radiative symmetrization to ##IMG## [http://ej.iop.org/icons/Entities/lesssim.gif]
	{lesssim} 1%. A 1-D average (over the target latitude) energy gain
	of G = 57 is calculated},
  file = {:Basko1993b.pdf:PDF},
  url = {http://stacks.iop.org/0029-5515/33/i=4/a=I08}
}

@ARTICLE{Basko1992,
  author = {M.M. Basko},
  title = {High gain DT targets for heavy ion beam fusion},
  journal = {Nuclear Fusion},
  year = {1992},
  volume = {32},
  pages = {1515},
  number = {9},
  abstract = {In a parametric study of reactor size DT targets driven by beams of
	heavy ions it was found that spark ignition and high energy gains
	can be achieved in four-layer single-shell targets irradiated by
	a nonshaped box pulse of 10 GeV 209 Bi ions. With an input energy
	of E in ?âà 6 MJ delivered in t in ?⧠10 ns, one-dimensional energy
	gains of G ##IMG## [http://ej.iop.org/icons/Entities/gtrsim.gif]
	{gtrsim} 400 are possible in the optimum cases. It is shown that,
	to obtain spark ignition and high energy gain, two conditions must
	be necessarily met: (1) a high enough implosion velocity, U ?àû ##IMG##
	[http://ej.iop.org/icons/Entities/gtrsim.gif] {gtrsim} 6.2 ?ó 10
	7 ?© -1/2 cm/s, must be reached, and (2) the fuel compression must
	be accomplished with a low enough pusher/fuel mass ratio, M p /M
	DT ##IMG## [http://ej.iop.org/icons/Entities/lesssim.gif] {lesssim}
	5-7 (?© is a dimensionless parameter determined by the density distribution
	in the compressed target core). It was found also that when the ##IMG##
	[http://ej.iop.org/icons/Entities/langle.gif] {langle} ?Å?îr ##IMG##
	[http://ej.iop.org/icons/Entities/rangle.gif] {rangle} of the cold
	part of the compressed fuel is ##IMG## [http://ej.iop.org/icons/Entities/simeq.gif]
	{simeq} 2-5 g/cm 2 , the main portion of the fuel is ignited owing
	to the heating by 14 MeV neutrons emitted from the central hot region},
  file = {:Basko1992.pdf:PDF},
  url = {http://stacks.iop.org/0029-5515/32/i=9/a=I02}
}

@ARTICLE{Basko1993a,
  author = {M M Basko},
  title = {Physics and prospects of inertial confinement fusion},
  journal = {Plasma Physics and Controlled Fusion},
  year = {1993},
  volume = {35},
  pages = {B81},
  number = {SB},
  abstract = {Some key physical aspects of the inertial confinement fusion (ICF)
	are discussed. The minimum scale of ICF microexplosions is determined
	by the ability to implode spherical shells with high radial convergence
	ratios C R and high initial aspect ratios A R0 . The attainable values
	of C R are limited by large-scale drive asymmetries, while the values
	of A R0 are constrained by the Rayleigh-Taylor instability. Under
	the indirect drive approach to ICF, it is easier to achieve the required
	uniformity of the drive pressure, but the penalty is a factor 4-5
	reduction of the target energy gain as compared to the direct drive
	option. Spark ignition is a crucial issue for indirect drive targets
	(at least for those to be used in power reactors), while the targets
	driven directly by heavy ion beams could, in principle, utilize a
	less demanding volume ignition scheme.},
  file = {:Basko1993a.pdf:PDF},
  url = {http://stacks.iop.org/0741-3335/35/i=SB/a=006}
}

@ARTICLE{Basko2002,
  author = {M. M. Basko and J. A. Maruhn and T. Schlegel},
  title = {Hydrodynamic instability of shells accelerated by direct ion beam
	heating},
  journal = {Physics of Plasmas},
  year = {2002},
  volume = {9},
  pages = {1348-1356},
  number = {4},
  doi = {10.1063/1.1462634},
  file = {:Basko2002.pdf:PDF},
  keywords = {plasma instability; Rayleigh-Taylor instability; plasma beam injection
	heating; plasma simulation},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/9/1348/1}
}

@ARTICLE{Basko1993,
  author = {Basko, M. M. and Meyer-ter-Vehn, J.},
  title = {Hotraum target for heavy ion inertial fusion},
  journal = {Nuclear Fusion},
  year = {1993},
  volume = {33},
  pages = {601},
  number = {4},
  abstract = {A new version of indirect drive target is proposed for heavy ion inertial
	fusion (HIIF), in which the cavity for radiative symmetrization is
	filled with a low density low Z material and is called a 'hotraum'.
	When heated to a temperature T ?â? 100 eV, the hotraum becomes transparent
	to thermal X-rays and ensures radiative smoothing of the energy flux
	which implodes the fuel capsule enclosed in the cavity. Ion beams
	are focused on the full target cross-section and deposit their energy
	in the high Z casing and in the outer region of the hotraum. The
	initial target configuration is spherical and requires no special
	orientation in the reactor chamber. Enhanced hydrodynamic efficiency
	of the capsule implosion, resulting from tamped ablation inside the
	hotraum, compensates for the high losses in the hotraum and leads
	to a beam-to-fuel energy coupling of about 5% and target gains in
	the range of 50-100. Hydrodynamic mapping of deposition nonuniformities
	onto the fusion capsule can be avoided by fast initial heating of
	the hotraum. A regime is found in which the ablating capsule insulates
	itself from hydrodynamic disturbances in the hotraum. The low density
	required for the hotraum fill allows stopping ranges of up to 100
	mg/cm 2 , corresponding to 6 GeV 209 Bi ions},
  file = {:Basko1993.pdf:PDF},
  url = {http://stacks.iop.org/0029-5515/33/i=4/a=I07}
}

@ARTICLE{swig,
  author = {Beazley,, D. M.},
  title = {Automated scientific software scripting with {SWIG}},
  journal = {Future Gener. Comput. Syst.},
  year = {2003},
  volume = {19},
  pages = {599--609},
  number = {5},
  address = {Amsterdam, The Netherlands, The Netherlands},
  doi = {http://dx.doi.org/10.1016/S0167-739X(02)00171-1},
  issn = {0167-739X},
  publisher = {Elsevier Science Publishers B. V.}
}

@INCOLLECTION{berger96,
  author = {M.J. Berger and R. Wang},
  title = {Multiple-Scattering Angular Deflections and Energy-Loss Straggling},
  booktitle = {Monte Carlo Transport of Electrons and Photons},
  publisher = {Plenum Press},
  year = {1987},
  editor = {Theodore M. Jenkins, Walter R. Nelson, and Alessandro Rindi}
}

@INCOLLECTION{berger63,
  author = {Martin J. Berger},
  title = {Monte Carlo Calculation of the Penetration and Diffusion of Fast
	Charged Particles},
  booktitle = {Methods in Computational Physics, Volume 1},
  publisher = {Academic Press},
  year = {1963},
  editor = {Berni Alder and Sidney Fernbach and Manuel Rotenberg}
}

@ARTICLE{Bethe1933,
  author = {H. A. Bethe},
  journal = {Handb. Physik},
  year = {1933},
  volume = {24/I},
  pages = {491},
  owner = {matt},
  timestamp = {2008.03.16}
}

@ARTICLE{Bethe1930,
  author = {Bethe, H. A.},
  journal = {Ann. Physik},
  year = {1930},
  volume = {5},
  pages = {325},
  owner = {matt},
  timestamp = {2008.03.16}
}

@ARTICLE{Betti2010,
  author = {R. Betti and P. Y. Chang and B. K. Spears and K. S. Anderson and
	J. Edwards and M. Fatenejad and J. D. Lindl and R. L. McCrory and
	R. Nora and D. Shvarts},
  title = {Thermonuclear ignition in inertial confinement fusion and comparison
	with magnetic confinement},
  journal = {Physics of Plasmas},
  year = {2010},
  volume = {17},
  pages = {058102},
  number = {5},
  eid = {058102},
  doi = {10.1063/1.3380857},
  keywords = {cryogenics; explosions; laser fusion; plasma pressure; plasma temperature},
  numpages = {10},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/17/058102/1}
}

@ARTICLE{Betti2005,
  author = {R. Betti and C. Zhou},
  title = {High-density and high-rho R fuel assembly for fast-ignition inertial
	confinement fusion},
  journal = {Physics of Plasmas},
  year = {2005},
  volume = {12},
  pages = {110702},
  number = {11},
  eid = {110702},
  doi = {10.1063/1.2127932},
  keywords = {fusion reactor fuel; fusion reactor ignition; plasma inertial confinement;
	explosions; fusion reactor design; fusion reactor targets},
  numpages = {4},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/12/110702/1}
}

@ARTICLE{Betti2007,
  author = {Betti, R. and Zhou, C. D. and Anderson, K. S. and Perkins, L. J.
	and Theobald, W. and Solodov, A. A.},
  title = {Shock Ignition of Thermonuclear Fuel with High Areal Density},
  journal = {Phys. Rev. Lett.},
  year = {2007},
  volume = {98},
  pages = {155001},
  number = {15},
  month = {Apr},
  doi = {10.1103/PhysRevLett.98.155001},
  file = {Betti2007.pdf:Betti2007.pdf:PDF},
  numpages = {4},
  publisher = {American Physical Society}
}

@ARTICLE{bielajew96,
  author = {Alex F. Bielajew},
  title = {A Hybrid multiple-scattering theory for electron-transport Monte
	Carlo calculations},
  journal = {Nuclear Instruments and Methods in Physics Research B},
  year = {1996},
  volume = {111},
  pages = {195-208},
  doi = {10.1016/0168-583X(95)01337-7},
  file = {bielajew96.pdf:bielajew96.pdf:PDF}
}

@ARTICLE{bielajew94,
  author = {Alex F. Bielajew},
  title = {Plural and multiple small-angle scattering from a screened Rutherford
	cross section},
  journal = {Nuclear Instruments and Methods in Physics Research B},
  year = {1994},
  volume = {86},
  pages = {257-269},
  doi = {10.1016/0168-583X(94)95288-4},
  file = {bielajew94.pdf:bielajew94.pdf:PDF}
}

@ARTICLE{Bohr1915,
  author = {Niels Bohr},
  title = {On the Decrease of Velocity of Swiftly Moving Electrified Particles
	in passing through Matter},
  journal = {Philosophical Magazine},
  year = {1915},
  volume = {30},
  pages = {581-612},
  owner = {mrterry},
  timestamp = {2008.03.03}
}

@ARTICLE{bosch92,
  author = {H. S. Bosch and G. M. Hale},
  title = {Improved Formulas for Fusion Cross-Sections and Thermal Reactivities},
  journal = {Nuclear Fusion},
  year = {1992},
  volume = {32},
  pages = {611},
  doi = {10.1088/0029-5515/32/4/I07},
  file = {bosch92.pdf:bosch92.pdf:PDF}
}

@INCOLLECTION{Braginskii1965,
  author = {S. I. Braginskii},
  title = {Transport Processes in a Plasma},
  booktitle = {Reviews of Plasma Physics},
  publisher = {Consultants Bureau},
  year = {1965},
  editor = {M. A. Leontovich},
  volume = {1},
  pages = {205-311},
  file = {Braginskii1965.pdf:Braginskii1965.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.03.04}
}

@ARTICLE{brown06,
  author = {Lowell S. Brown and Dean L Preston and Robert L Singleton Jr},
  title = {Plasma stopping power including subleading order},
  journal = {Journal of Physics},
  year = {2006},
  volume = {39},
  pages = {4667-4670},
  doi = {http://dx.doi.org/10.1088/0305-4470/39/17/S54},
  file = {brown06.pdf:brown06.pdf:PDF}
}

@ARTICLE{Brown2005,
  author = {Lowell S. Brown and Dean L. Preston and Robert L. Singleton Jr.},
  title = {Charged particle motion in a highly ionized plasma},
  journal = {Physics Reports},
  year = {2005},
  volume = {410},
  pages = {237-333},
  abstract = {A recently introduced method utilizing dimensional continuation is
	employed to compute the energy loss rate for a non-relativistic particle
	moving through a highly ionized plasma. No restriction is made on
	the charge, mass, or speed of this particle. It is, however, assumed
	that the plasma is not strongly coupled in the sense that the dimensionless
	plasma coupling parameter g=e2?D/4?T is small, where ?D is the Debye
	wave number of the plasma. To leading and next-to-leading order in
	this coupling, dE/dx is of the generic form Click to view the MathML
	source. The precise numerical coefficient out in front of the logarithm
	is well known. We compute the constant C under the logarithm exactly
	for arbitrary particle speeds. Our exact results differ from approximations
	given in the literature. The differences are in the range of 20%
	for cases relevant to inertial confinement fusion experiments. The
	same method is also employed to compute the rate of momentum loss
	for a projectile moving in a plasma, and the rate at which two plasmas
	at different temperatures come into thermal equilibrium. Again these
	calculations are done precisely to the order given above. The loss
	rates of energy and momentum uniquely define a Fokker?Planck equation
	that describes particle motion in the plasma. The coefficients determined
	in this way are thus well-defined, contain no arbitrary parameters
	or cutoffs, and are accurate to the order described. This Fokker?Planck
	equation describes the straggling?the spreading in the longitudinal
	position of a group of particles with a common initial velocity and
	position?and the transverse diffusion of a beam of particles. It
	should be emphasized that our work does not involve a model, but
	rather it is a precisely defined evaluation of the leading terms
	in a well-defined perturbation theory.},
  doi = {10.1016/j.physrep.2005.01.001},
  file = {Brown2005.pdf:Brown2005.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.03.28}
}

@ARTICLE{Brown2007,
  author = {Brown, Lowell S. and Singleton, Robert L.},
  title = {Temperature equilibration rate with Fermi-Dirac statistics},
  journal = {Phys. Rev. E},
  year = {2007},
  volume = {76},
  pages = {066404},
  number = {6},
  month = {Dec},
  doi = {10.1103/PhysRevE.76.066404},
  numpages = {21},
  publisher = {American Physical Society}
}

@ARTICLE{Brown2001,
  author = {Lowell S. Brown and Laurence G. Yaffe},
  title = {Effective field theory for highly ionized plasmas},
  journal = {Physics Reports},
  year = {2001},
  volume = {340},
  pages = {1 - 164},
  number = {1-2},
  abstract = {We examine the equilibrium properties of hot, non-relativistic plasmas.
	The partition function and density correlation functions of a plasma
	with several species are expressed in terms of a functional integral
	over electrostatic potential distributions. This is a convenient
	formulation for performing a perturbative expansion. The theory is
	made well-defined at every stage by employing dimensional regularization
	which, among other virtues, automatically removes the unphysical
	(infinite) Coulomb self-energy contributions. The leading order,
	field-theoretic tree approximation automatically includes the effects
	of Debye screening. No further partial resummations are needed for
	this effect. Subleading, one-loop corrections are easily evaluated.
	The two-loop corrections, however, have ultraviolet divergences.
	These correspond to the short-distance, logarithmic divergence which
	is encountered in the spatial integral of the Boltzmann exponential
	when it is expanded to third order in the Coulomb potential. Such
	divergences do not appear in the underlying quantum theory - they
	are rendered finite by quantum fluctuations. We show how such divergences
	may be removed and the correct finite theory obtained by introducing
	additional local interactions in the manner of modern effective quantum
	field theories. We compute the two-loop induced coupling by exploiting
	a non-compact su(1, 1) symmetry of the hydrogen atom. This enables
	us to obtain explicit results for density-density correlation functions
	through two-loop order and thermodynamic quantities through three-loop
	order. The induced couplings are shown to obey renormalization group
	equations, and these equations are used to characterize all leading
	logarithmic contributions in the theory. A linear combination of
	pressure plus energy and number densities is shown to be described
	by a field-theoretic anomaly. The effective Lagrangian method that
	we employ yields a simple demonstration that, at long distance, correlation
	functions have an algebraic fall off (because of quantum effects)
	rather than the exponential damping of classical Debye screening.
	We use the effective theory to compute, easily and explicitly, this
	leading long-distance behavior of density correlation functions.
	The presentation is pedagogical and self-contained. The results for
	thermodynamic quantities at three-loop [or O(n5/2)] order, and for
	the leading long-distance forms of correlation functions, agree with
	previous results in the literature, but they are obtained in a novel
	and simple fashion using the effective field theory. In addition
	to the new construction of the effective field theory for plasma
	physics, we believe that the results we report for the explicit form
	of correlation functions at two-loop order, as well as the determination
	of higher-order leading-logarithmic contributions, are also original.},
  doi = {DOI: 10.1016/S0370-1573(00)00068-5},
  file = {Brown2001.pdf:Brown2001.pdf:PDF},
  issn = {0370-1573},
  keywords = {Non-relativistic plasma thermodynamics},
  url = {http://www.sciencedirect.com/science/article/B6TVP-41S4T83-2/2/22a7a4e70e56642f68f4c99f57e34210}
}

@ARTICLE{Brown1972,
  author = {Brown, M. D. and Moak, C. D.},
  title = {Stopping Powers of Some Solids for 30-90-MeV $U238$ Ions},
  journal = {Phys. Rev. B},
  year = {1972},
  volume = {6},
  pages = {90--94},
  number = {1},
  month = {Jul},
  doi = {10.1103/PhysRevB.6.90},
  file = {Brown1972.pdf:Brown1972.pdf:PDF},
  numpages = {4},
  publisher = {American Physical Society}
}

@ARTICLE{Brown1997,
  author = {Brown,S. R. and Haines,M. G.},
  title = {Transport in partially degenerate, magnetized plasmas. Part 1. Collision
	operators},
  journal = {Journal of Plasma Physics},
  year = {1997},
  volume = {58},
  pages = {577-600},
  number = {04},
  abstract = { ABSTRACT The quantum Boltzmann collision operator is expanded to
	yield a degenerate form of the Fokker–Planck collision operator.
	This is analysed using Rosenbluth potentials to give a degenerate
	analogue of the Shkarofsky operator. The distribution function is
	then expanded about an equilibrium Fermi–Dirac distribution
	function using a tensor perturbation formulation to give a zeroth-order
	and a first-order collision operator. These equations are shown to
	satisfy the relevant conservation equations. It is shown that the
	distribution function relaxes to a Fermi–Dirac form through
	electron–electron collisions. },
  doi = {10.1017/S0022377897006041},
  eprint = {http://journals.cambridge.org/article_S0022377897006041},
  file = {Brown2000.pdf:Brown2000.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.03.04},
  url = {http://journals.cambridge.org/action/displayAbstract?fromPage=online&aid=18221&fulltextType=RA&fileId=S0022377897006041}
}

@ARTICLE{Brueckner1974,
  author = {Brueckner, Keith A. and Jorna, Siebe},
  title = {Laser-driven fusion},
  journal = {Rev. Mod. Phys.},
  year = {1974},
  volume = {46},
  pages = {325--367},
  number = {2},
  month = {Apr},
  doi = {10.1103/RevModPhys.46.325},
  file = {Brueckner1974.pdf:Brueckner1974.pdf:PDF},
  numpages = {42},
  owner = {mterry},
  timestamp = {2007.10.31}
}

@ARTICLE{Brysk1974,
  author = {H Brysk},
  title = {Electron-ion equilibration in a partially degenerate plasma},
  journal = {Plasma Physics},
  year = {1974},
  volume = {16},
  pages = {927-932},
  number = {10},
  abstract = {Expressions are derived for the energy loss rate of a fast ion to
	electrons as it slows down in a plasma of arbitrary electron degeneracy
	and for the equilibration of the ions and electrons in the plasma.},
  doi = {10.1088/0032-1028/16/10/005},
  file = {Brysk1974.pdf:Brysk1974.pdf:PDF},
  owner = {mterry},
  timestamp = {2007.11.01},
  url = {http://stacks.iop.org/0032-1028/16/927}
}

@ARTICLE{brysk73,
  author = {H Brysk},
  title = {Fusion neutron energies and spectra},
  journal = {Plasma Physics},
  year = {1973},
  volume = {15},
  pages = {611-617},
  number = {7},
  abstract = {The interaction of two Maxwellian distributions of particles will
	differ from the interaction of the two particles at their respective
	Maxwell averages if the strength of the interaction varies significantly
	with energy over the widths of the distributions. This effect is
	considered here in particular for fusion (both D-T and D-D) for the
	mean energy of the reacting particles as a function of temperature
	and for the spectrum of the neutrons produced.},
  doi = {10.1088/0032-1028/15/7/001},
  file = {brysk73.pdf:brysk73.pdf:PDF},
  url = {http://stacks.iop.org/0032-1028/15/611}
}

@ARTICLE{Brysk1975,
  author = {Brysk, H and Campbell, P. M. and Hammerling, P.},
  title = {Thermal Conduction in Laser Fusion},
  journal = {Plasma Physics},
  year = {1975},
  volume = {17},
  pages = {473-484},
  doi = {10.1088/0032-1028/17/6/007},
  file = {Brysk1975.pdf:Brysk1975.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.03.10}
}

@ARTICLE{Phipps1988,
  author = {C. R. Phipps, Jr. and T. P. Turner and R. F. Harrison and G. W. York
	and W. Z. Osborne and G. K. Anderson and X. F. Corlis and L. C. Haynes
	and H. S. Steele and K. C. Spicochi and T. R. King},
  title = {Impulse coupling to targets in vacuum by KrF, HF, and CO[sub 2] single-pulse
	lasers},
  journal = {Journal of Applied Physics},
  year = {1988},
  volume = {64},
  pages = {1083-1096},
  number = {3},
  doi = {10.1063/1.341867},
  keywords = {LASERPRODUCED PLASMA; PULSE TECHNIQUES; ABLATION; MATHEMATICAL MODELS;
	SOLIDS; PHYSICAL RADIATION EFFECTS; LASER RADIATION; CARBON DIOXIDE
	LASERS; KRYPTON FLUORIDE LASERS},
  publisher = {AIP},
  url = {http://link.aip.org/link/?JAP/64/1083/1}
}

@ARTICLE{Cereceda2000,
  author = {Carlo Cereceda and Claude Deutsch and Michel De Peretti and Michel
	Sabatier and Hrachya B. Nersisyan},
  title = {Dielectric response function and stopping power of dense magnetized
	plasma},
  journal = {Physics of Plasmas},
  year = {2000},
  volume = {7},
  pages = {2884-2893},
  doi = {10.1063/1.874138},
  file = {Cereceda2000.pdf:Cereceda2000.pdf:PDF},
  owner = {mterry},
  timestamp = {2007.10.29}
}

@ARTICLE{Chandrasekhar1949,
  author = {Chandrasekhar, S.},
  title = {Brownian Motion, Dynamical Friction, and Stellar Dynamics},
  journal = {Reviews of Modern Physics},
  year = {1949},
  volume = {21},
  pages = {383-388},
  owner = {mrterry},
  timestamp = {2008.03.04}
}

@BOOK{Chandrasekhar1942,
  title = {Principles of Stellar Dynamics},
  publisher = {University of Chicago Press},
  year = {1942},
  author = {Chandrasekhar, S.},
  owner = {mrterry},
  timestamp = {2008.03.04}
}

@ARTICLE{Chang2010,
  author = {Chang, PY. and Betti, R. and Spears, B. K. and Anderson, K. S. and
	Edwards, J. and Fatenejad, M. and Lindl, J. D. and McCrory, R. L.
	and Nora, R. and Shvarts, D.},
  title = {Generalized Measurable Ignition Criterion for Inertial Confinement
	Fusion},
  journal = {Phys. Rev. Lett.},
  year = {2010},
  volume = {104},
  pages = {135002},
  month = {Apr},
  doi = {10.1103/PhysRevLett.104.135002},
  file = {Chang2010.pdf:Chang2010.pdf:PDF},
  issue = {13},
  numpages = {4},
  publisher = {American Physical Society},
  url = {http://link.aps.org/doi/10.1103/PhysRevLett.104.135002}
}

@BOOK{Chapman1953,
  title = {Mathematical Theory of Nonuniform Gases},
  publisher = {Cambridge University Press},
  year = {1953},
  author = {Sydney Chapman and T. G. Cowling},
  owner = {mrterry},
  timestamp = {2008.03.04}
}

@INPROCEEDINGS{VisIt,
  author = {Hank Childs AND Eric S. Brugger AND Kathleen S. Bonnell AND Jeremy
	S. Meredith AND Mark Miller AND Brad J. Whitlock AND Nelson Max},
  title = {A Contract-Based System for Large Data Visualization},
  booktitle = {Proceedings of IEEE Visualization 2005},
  year = {2005},
  pages = {190--198},
  abstract = {VisIt is a richly featured visualization tool that is used to visualize
	some of the largest simulations ever run. The scale of these simulations
	requires that optimizations are incorporated into every operation
	VisIt performs. But the set of applicable optimizations that VisIt
	can perform is dependent on the types of operations being done. Complicating
	the issue, VisIt has a plugin capability that allows new, unforeseen
	components to be added, making it even harder to determine which
	optimizations can be applied. We introduce the concept of a contract
	to the standard data flow network design. This contract enables each
	component of the data flow network to modify the set of optimizations
	used. In addition, the contract allows for new components to be accommodated
	gracefully within VisIt's data flow network system. },
  eventtime = {October 23--25, 2005},
  journal = {IEEE Visualization 2005},
  keywords = {large data, data flow networks, contract-based system},
  location = {Minneapolis, Minnesota}
}

@ARTICLE{scalapack,
  author = {J. Choi and J. Demmel and I. Dhillon and J. Dongarra and S. Ostrouchov
	and A. Petitet and K. Stanley and D. Walker and R.C. Whaley},
  title = {ScaLAPACK: a portable linear algebra library for distributed memory
	computers — design issues and performance},
  journal = {Computer Physics Communications},
  year = {1996},
  volume = {97},
  pages = {1 - 15},
  number = {1–2},
  note = {<ce:title>High-Performance Computing in Science</ce:title>},
  abstract = {This paper outlines the content and performance of ScaLAPACK, a collection
	of mathematical software for linear algebra computations on distributed
	memory computers. The importance of developing standards for computational
	and message passing interfaces is discussed. We present the different
	components and building blocks of ScaLAPACK. This paper outlines
	the difficulties inherent in producing correct codes for networks
	of heterogeneous processors. We define a theoretical model of parallel
	computers dedicated to linear algebra applications: the Distributed
	Linear Algebra Machine (DLAM). This model provides a convenient framework
	for developing parallel algorithms and investigating their scalability,
	performance and programmability. Extensive performance results on
	various platforms are presented and analyzed with the help of the
	DLAM. Finally, this paper briefly describes future directions for
	the ScaLAPACK library and concludes by suggesting alternative approaches
	to mathematical libraries, explaining how ScaLAPACK could be integrated
	into efficient and user-friendly distributed systems.},
  doi = {10.1016/0010-4655(96)00017-3},
  issn = {0010-4655},
  url = {http://www.sciencedirect.com/science/article/pii/0010465596000173}
}

@ARTICLE{Collins2012,
  author = {T. J. B. Collins and J. A. Marozas and K. S. Anderson and R. Betti
	and R. S. Craxton and J. A. Delettrez and V. N. Goncharov and D.
	R. Harding and F. J. Marshall and R. L. McCrory and D. D. Meyerhofer
	and P. W. McKenty and P. B. Radha and A. Shvydky and S. Skupsky and
	J. D. Zuegel},
  title = {A polar-drive--ignition design for the National Ignition Facility},
  journal = {Physics of Plasmas},
  year = {2012},
  volume = {19},
  pages = {056308},
  number = {5},
  eid = {056308},
  doi = {10.1063/1.3693969},
  keywords = {fusion reactor ignition; plasma inertial confinement; plasma light
	propagation; surface roughness},
  numpages = {12},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/19/056308/1}
}

@ARTICLE{Collins2007,
  author = {T. J. B. Collins and J. A. Marozas and R. Betti and D. R. Harding
	and P. W. McKenty and P. B. Radha and S. Skupsky and V. N. Goncharov
	and J. P. Knauer and R. L. McCrory},
  title = {One-megajoule, wetted-foam target-design performance for the National
	Ignition Facility},
  journal = {Physics of Plasmas},
  year = {2007},
  volume = {14},
  pages = {056308},
  number = {5},
  eid = {056308},
  doi = {10.1063/1.2709859},
  file = {:Collins2007.pdf:PDF},
  keywords = {polymer foams; fusion reactor targets; fusion reactor design; fusion
	reactor ignition; plasma light propagation; plasma instability; plasma
	simulation; plasma inertial confinement},
  numpages = {10},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/14/056308/1}
}

@ARTICLE{Collins2005,
  author = {T. J. B. Collins and A. Poludnenko and A. Cunningham and A. Frank},
  title = {Shock propagation in deuterium-tritium-saturated foam},
  journal = {Physics of Plasmas},
  year = {2005},
  volume = {12},
  pages = {062705},
  number = {6},
  eid = {062705},
  doi = {10.1063/1.1927099},
  file = {:Collins2005.pdf:PDF},
  keywords = {deuterium; tritium; foams; plasma shock waves; plasma simulation;
	plasma fluctuations; plasma transport processes; plasma turbulence},
  numpages = {12},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/12/062705/1}
}

@ARTICLE{Collins2002,
  author = {T. J. B. Collins and S. Skupsky},
  title = {Imprint reduction using an intensity spike in OMEGA cryogenic targets},
  journal = {Physics of Plasmas},
  year = {2002},
  volume = {9},
  pages = {275-281},
  number = {1},
  doi = {10.1063/1.1425840},
  keywords = {laser fusion; fusion reactor targets; Rayleigh-Taylor instability;
	plasma simulation},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/9/275/1}
}

@ARTICLE{Colombant2005,
  author = {D. G. Colombant and W. M. Manheimer and M. Busquet},
  title = {Test of models for electron transport in laser produced plasmas},
  journal = {Physics of Plasmas},
  year = {2005},
  volume = {12},
  pages = {072702},
  number = {7},
  eid = {072702},
  doi = {10.1063/1.1929777},
  file = {Colombant2005.pdf:Colombant2005.pdf:PDF},
  keywords = {plasma transport processes; explosions; Fokker-Planck equation; plasma
	temperature; plasma simulation; fusion reactor targets; laser fusion},
  numpages = {14},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/12/072702/1}
}

@INPROCEEDINGS{global-arrays-python,
  author = {Daily, Jeff and Lewis, Robert R.},
  title = {Poster: automatic parallelization of numerical python applications
	using the global arrays toolkit},
  booktitle = {Proceedings of the 2011 companion on High Performance Computing Networking,
	Storage and Analysis Companion},
  year = {2011},
  series = {SC '11 Companion},
  pages = {43--44},
  address = {New York, NY, USA},
  publisher = {ACM},
  acmid = {2148623},
  doi = {10.1145/2148600.2148623},
  isbn = {978-1-4503-1030-7},
  keywords = {GAIN, NumPy, PGAS, global arrays, python},
  location = {Seattle, Washington, USA},
  numpages = {2},
  url = {http://doi.acm.org/10.1145/2148600.2148623}
}

@MISC{petsc4py-web-page,
  author = {Lisandro Dalcin},
  title = {{PETSc} for {Python} -- {Python} bindings for {PETSc} libraries},
  howpublished = {\url{http://code.google.com/p/petsc4py/}},
  note = {http://code.google.com/p/petsc4py/}
}

@ARTICLE{Debye1923,
  author = {P. Debye and E. Huckle},
  journal = {Phys. Z},
  year = {1923},
  volume = {24},
  pages = {185},
  owner = {mrterry},
  timestamp = {2010.08.08}
}

@ARTICLE{Densmore2007,
  author = {Jeffery D. Densmore and Todd J. Urbatsch and Thomas M. Evans and
	Michael W. Buksas},
  title = {A hybrid transport-diffusion method for Monte Carlo radiative-transport
	simulations},
  journal = {Journal of Computational Physics},
  year = {2007},
  volume = {222},
  pages = {485-503},
  doi = {10.1016/j.jcp.2006.07.031},
  file = {Densmore2007.pdf:Densmore2007.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.04.11}
}

@ELECTRONIC{icf_diagram,
  author = {Benjamin D. Esham},
  month = {July},
  year = {2007},
  organization = {Wikipedia},
  url = {http://en.wikipedia.org/wiki/File:Inertial_confinement_fusion.svg},
  owner = {mrterry},
  timestamp = {2010.08.02}
}

@ARTICLE{Evans1983,
  author = {Evans,R. G.},
  title = {A simple model of ion beam heated ICF targets},
  journal = {Laser and Particle Beams},
  year = {1983},
  volume = {1},
  pages = {231-239},
  number = {03},
  doi = {10.1017/S0263034600000318},
  eprint = {http://journals.cambridge.org/article_S0263034600000318},
  file = {Evans1983.pdf:Evans1983.pdf:PDF},
  url = {http://dx.doi.org/10.1017/S0263034600000318}
}

@ARTICLE{fano63,
  author = {U. Fano},
  title = {Penetration of Protons, Alpha Particles, and Mesons},
  journal = {Annual Review of Nuclear Science},
  year = {1963},
  volume = {13},
  pages = {1-66},
  file = {fano63.pdf:fano63.pdf:PDF},
  owner = {mterry},
  timestamp = {2007.10.29}
}

@ARTICLE{Fano1953,
  author = {Fano, U.},
  title = {Degradation and Range Straggling of High-Energy Radiations},
  journal = {Phys. Rev.},
  year = {1953},
  volume = {92},
  pages = {328--349},
  number = {2},
  month = {Oct},
  doi = {10.1103/PhysRev.92.328},
  file = {Fano1953.pdf:Fano1953.pdf:PDF},
  numpages = {21},
  owner = {matt},
  publisher = {American Physical Society},
  timestamp = {2008.03.18}
}

@ARTICLE{Fatenejad2008,
  author = {Milad Fatenejad and Gregory A. Moses},
  title = {Extension of Kershaw diffusion scheme to hexahedral meshes},
  journal = {Journal of Computational Physics},
  year = {2008},
  volume = {227},
  pages = {2187-2197},
  doi = {10.1016/j.jcp.2007.11.001},
  file = {Fatenejad2008.pdf:Fatenejad2008.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.04.18}
}

@ARTICLE{Fermi1940,
  author = {Fermi, Enrico},
  title = {The Ionization Loss of Energy in Gases and in Condensed Materials},
  journal = {Phys. Rev.},
  year = {1940},
  volume = {57},
  pages = {485--493},
  number = {6},
  month = {Mar},
  doi = {10.1103/PhysRev.57.485},
  file = {Fermi1940.pdf:Fermi1940.pdf:PDF},
  numpages = {8},
  owner = {matt},
  publisher = {American Physical Society},
  timestamp = {2008.03.18}
}

@ARTICLE{Fermi1939,
  author = {Fermi, Enrico},
  title = {The Absorption of Mesotrons in Air and in Condensed Materials},
  journal = {Phys. Rev.},
  year = {1939},
  volume = {56},
  pages = {1242},
  number = {12},
  month = {Dec},
  doi = {10.1103/PhysRev.56.1242},
  file = {Fermi1939.pdf:Fermi1939.pdf:PDF},
  numpages = {1},
  owner = {matt},
  publisher = {American Physical Society},
  timestamp = {2008.03.18}
}

@ARTICLE{Fermi1947,
  author = {Fermi, E. and Teller, E.},
  title = {The Capture of Negative Mesotrons in Matter},
  journal = {Phys. Rev.},
  year = {1947},
  volume = {72},
  pages = {399--408},
  number = {5},
  month = {Sep},
  doi = {10.1103/PhysRev.72.399},
  file = {Fermi1947.pdf:Fermi1947.pdf:PDF},
  numpages = {9},
  owner = {mterry},
  timestamp = {2007.10.30}
}

@ARTICLE{Ferrariis1984,
  author = {de Ferrariis, Leonardo and Arista, N\'estor R.},
  title = {Classical and quantum-mechanical treatments of the energy loss of
	charged particles in dilute plasmas},
  journal = {Phys. Rev. A},
  year = {1984},
  volume = {29},
  pages = {2145--2159},
  number = {4},
  month = {Apr},
  note = {Be sure to check errata!},
  doi = {10.1103/PhysRevA.29.2145},
  file = {Ferrariis1984.pdf:Ferrariis1984.pdf:PDF},
  numpages = {14},
  owner = {mterry},
  timestamp = {2007.11.01}
}

@ARTICLE{Fleck1971,
  author = {Fleck, Jr., J. A. and Cummings, Jr., J.D.},
  title = {An implicit Monte Carlo scheme for calculating time and frequency
	dependent nonlinear radiation transport},
  journal = {Journal of Computational Physics},
  year = {1971},
  volume = {8},
  pages = {313-342},
  doi = {10.1016/0021-9991(71)90015-5},
  file = {Fleck1971.pdf:Fleck1971.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.04.18}
}

@ARTICLE{Fraley1974,
  author = {G. S. Fraley and E. J. Linnebur and R. J. Mason and R. L. Morse},
  title = {Thermonuclear burn characteristics of compressed deuterium-tritium
	microspheres},
  journal = {Physics of Fluids},
  year = {1974},
  volume = {17},
  pages = {474-489},
  number = {2},
  doi = {10.1063/1.1694739},
  file = {Fraley1974.pdf:Fraley1974.pdf:PDF},
  owner = {mrterry},
  publisher = {AIP},
  timestamp = {2008.03.03},
  url = {http://link.aip.org/link/?PFL/17/474/1}
}

@ARTICLE{Frieman1963,
  author = {E. A. Frieman and D. L. Book},
  title = {Convergent Classical Kinetic Equation for a Plasma},
  journal = {Physics of Fluids},
  year = {1963},
  volume = {6},
  pages = {1700-1706},
  number = {12},
  abstract = {A kinetic equation for a plasma of electrons and infinite mass ions
	is derived which exhibits no divergences for any impact parameter.
	The basic expansion used is in nlambda<sub>D</sub><sup>3</sup>, the
	number of particles in a Debye sphere. The collision operator has
	Boltzmann, Fokker-Planck, and Lenard-Balescu behavior in the appropriate
	impact parameter regimes.},
  doi = {10.1063/1.1711012},
  file = {Frieman1963.pdf:Frieman1963.pdf:PDF},
  owner = {mrterry},
  publisher = {AIP},
  timestamp = {2008.03.28},
  url = {http://link.aip.org/link/?PFL/6/1700/1}
}

@ARTICLE{Geller1997,
  author = {David K. Geller and Jon C. Weisheit},
  title = {Classical electron-ion scattering in strongly magnetized plasmas.
	I. A generalized Coulomb logarithm},
  journal = {Physics of Plasmas},
  year = {1997},
  volume = {4},
  pages = {4258-4271},
  doi = {10.1063/1.872589},
  file = {Geller1997.pdf:Geller1997.pdf:PDF},
  owner = {mterry},
  timestamp = {2007.10.29}
}

@ARTICLE{Gentile2000,
  author = {N. A. Gentile},
  title = {Implicit Monte Carlo Diffusion - An Acceleration Method for Monte
	Carlo Time Dependent Radiative Transfer Simulations},
  journal = {UCRL},
  year = {2000},
  volume = {UCRL-ID-141467},
  pages = {1-24},
  file = {Gentile2000.pdf:Gentile2000.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.04.14}
}

@ARTICLE{Glinsky1992,
  author = {Michael E. Glinsky and Thomas M. O'Neil and Marshall N. Rosenbluth
	and Kenji Tsuruta and Setsuo Ichimaru},
  title = {Collisional equipartition rate for a magnetized pure electron plasma},
  journal = {Physics of Fluids B: Plasma Physics},
  year = {1992},
  volume = {4},
  pages = {1156-1166},
  doi = {10.1063/1.860124},
  file = {Glinsky1992.pdf:Glinsky1992.pdf:PDF},
  owner = {mterry},
  timestamp = {2007.10.29}
}

@ARTICLE{Glosli2008,
  author = {Glosli, J. N. and Graziani, F. R. and More, R. M. and Murillo, M.
	S. and Streitz, F. H. and Surh, M. P. and Benedict, L. X. and Hau-Riege,
	S. and Langdon, A. B. and London, R. A.},
  title = {Molecular dynamics simulations of temperature equilibration in dense
	hydrogen},
  journal = {Phys. Rev. E},
  year = {2008},
  volume = {78},
  pages = {025401},
  number = {2},
  month = {Aug},
  doi = {10.1103/PhysRevE.78.025401},
  numpages = {4},
  publisher = {American Physical Society}
}

@ARTICLE{Goano1997,
  author = {Goano, Michele},
  title = {Remark on Algorithm 745},
  journal = {ACM Trans. Math. Softw.},
  year = {1997},
  volume = {23},
  pages = {295--295},
  number = {2},
  address = {New York, NY, USA},
  doi = {http://doi.acm.org/10.1145/264029.643581},
  file = {Goano1997.pdf:Goano1997.pdf:PDF},
  issn = {0098-3500},
  owner = {mrterry},
  publisher = {ACM},
  timestamp = {2008.03.10}
}

@ARTICLE{Goano1995,
  author = {Michele Goano},
  title = {Algorithm 745: computation of the complete and incomplete Fermi-Dirac
	integral},
  journal = {ACM Trans. Math. Softw.},
  year = {1995},
  volume = {21},
  pages = {221--232},
  number = {3},
  address = {New York, NY, USA},
  doi = {http://doi.acm.org/10.1145/210089.210090},
  file = {Goano1995.pdf:Goano1995.pdf:PDF},
  issn = {0098-3500},
  owner = {mrterry},
  publisher = {ACM},
  timestamp = {2008.03.10}
}

@ARTICLE{Goncharov2006,
  author = {Goncharov VN, Gotchev OV, Vianello E, Boehly TR, Knauer JP, McKenty
	PW, Radha PB, Regan SP, Sangster TC, Skupsky S, Smalyuk VA, Betti
	R, McCrory RL, Meyerhofer DD, Cherfils-Clerouin C},
  title = {Early stage of implosion in inertial confinement fusion: Shock timing
	and perturbation evolution},
  journal = {Physics of Plasmas},
  year = {2006},
  volume = {13},
  pages = {012702},
  doi = {10.1063/1.2162803},
  file = {Goncharov2006.pdf:Goncharov2006.pdf:PDF},
  owner = {mrterry},
  timestamp = {2007.11.27}
}

@ARTICLE{Goncharov2003,
  author = {V. N. Goncharov and J. P. Knauer and P. W. McKenty and P. B. Radha
	and T. C. Sangster and S. Skupsky and R. Betti and R. L. McCrory
	and D. D. Meyerhofer},
  title = {Improved performance of direct-drive inertial confinement fusion
	target designs with adiabat shaping using an intensity picket},
  journal = {Physics of Plasmas},
  year = {2003},
  volume = {10},
  pages = {1906-1918},
  number = {5},
  doi = {10.1063/1.1562166},
  keywords = {fusion reactor targets; cryogenics; fusion reactor design; rough surfaces;
	laser fusion; entropy; plasma thermodynamics; plasma shock waves;
	Rayleigh-Taylor instability},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/10/1906/1}
}

@ARTICLE{Goncharov2008,
  author = {V. N. Goncharov and T. C. Sangster and P. B. Radha and R. Betti and
	T. R. Boehly and T. J. B. Collins and R. S. Craxton and J. A. Delettrez
	and R. Epstein and V. Yu. Glebov and S. X. Hu and I. V. Igumenshchev
	and J. P. Knauer and S. J. Loucks and J. A. Marozas and F. J. Marshall
	and R. L. McCrory and P. W. McKenty and D. D. Meyerhofer and S. P.
	Regan and W. Seka and S. Skupsky and V. A. Smalyuk and J. M. Soures
	and C. Stoeckl and D. Shvarts and J. A. Frenje and R. D. Petrasso
	and C. K. Li and F. Seguin and W. Manheimer and D. G. Colombant},
  title = {Performance of direct-drive cryogenic targets on OMEGA},
  journal = {Physics of Plasmas},
  year = {2008},
  volume = {15},
  pages = {056310},
  number = {5},
  eid = {056310},
  doi = {10.1063/1.2856551},
  file = {:Goncharov2008.pdf:PDF},
  keywords = {cryogenics; fusion reactor targets; laser fusion},
  numpages = {8},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/15/056310/1}
}

@ARTICLE{goudsmit40_1,
  author = {Goudsmit, S. and Saunderson, J. L.},
  title = {Multiple Scattering of Electrons},
  journal = {Phys. Rev.},
  year = {1940},
  volume = {57},
  pages = {24--29},
  number = {1},
  month = {Jan},
  doi = {10.1103/PhysRev.57.24},
  file = {goudsmit40_1.pdf:goudsmit40_1.pdf:PDF},
  numpages = {5}
}

@ARTICLE{goudsmit40_2,
  author = {Goudsmit, S. and Saunderson, J. L.},
  title = {Multiple Scattering of Electrons. II},
  journal = {Phys. Rev.},
  year = {1940},
  volume = {58},
  pages = {36--42},
  number = {1},
  month = {Jul},
  doi = {10.1103/PhysRev.58.36},
  file = {goudsmit40_2.pdf:goudsmit40_2.pdf:PDF},
  numpages = {6}
}

@ARTICLE{Gould1967,
  author = {Gould, Harvey A. and DeWitt, Hugh E.},
  title = {Convergent Kinetic Equation for a Classical Plasma},
  journal = {Phys. Rev.},
  year = {1967},
  volume = {155},
  pages = {68--74},
  number = {1},
  month = {Mar},
  doi = {10.1103/PhysRev.155.68},
  file = {Gould1967.pdf:Gould1967.pdf:PDF},
  numpages = {6},
  owner = {matt},
  publisher = {American Physical Society},
  timestamp = {2008.03.21}
}

@ARTICLE{Grecos1975,
  author = {Grecos, A. and Guo, T. and Guo, W.},
  title = {Some Formal Aspects of Subdynamics},
  journal = {Physica},
  year = {1975},
  volume = {80A},
  pages = {421-446},
  file = {Grecos1975.pdf:Grecos1975.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.04.03}
}

@ARTICLE{Grote2005,
  author = {David P. Grote and Alex Friedman and Jean-Luc Vay and Irving Haber},
  title = {The WARP Code: Modeling High Intensity Ion Beams},
  journal = {AIP Conference Proceedings},
  year = {2005},
  volume = {749},
  pages = {55-58},
  number = {1},
  doi = {10.1063/1.1893366},
  editor = {Matthaeus Leitner},
  keywords = {ion beams; cyclotron resonance; ion sources; computer aided analysis},
  publisher = {AIP},
  url = {http://link.aip.org/link/?APC/749/55/1}
}

@MISC{HDF5,
  author = {The HDF Group},
  title = {{HDF}5: {API} Specification Reference Manual},
  owner = {mrterry},
  timestamp = {2010.06.06},
  url = {http://www.hdfgroup.org/HDF5/doc/RM/RM_H5Front.html}
}

@ARTICLE{Haan1995,
  author = {Steven W. Haan and Stephen M. Pollaine and John D. Lindl and Laurance
	J. Suter and Richard L. Berger and Linda V. Powers and W. Edward
	Alley and Peter A. Amendt and John A. Futterman and W. Kirk Levedahl
	and Mordecai D. Rosen and Dana P. Rowley and Richard A. Sacks and
	Aleksei I. Shestakov and George L. Strobel and Max Tabak and Stephen
	V. Weber and George B. Zimmerman and William J. Krauser and Douglas
	C. Wilson and Stephen V. Coggeshall and David B. Harris and Nelson
	M. Hoffman and Bernhard H. Wilde},
  title = {Design and modeling of ignition targets for the National Ignition
	Facility},
  journal = {Physics of Plasmas},
  year = {1995},
  volume = {2},
  pages = {2480-2487},
  number = {6},
  doi = {10.1063/1.871209},
  keywords = {ICF DEVICES; LASERPRODUCED PLASMA; THERMONUCLEAR IGNITION; TARGETS;
	ABLATION; X RADIATION; GOLD; BERYLLIUM; POLYSTYRENE; HOT SPOTS; DEUTERIUM;
	TRITIUM},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/2/2480/1}
}

@ARTICLE{Halen1985,
  author = {P. Van Halen and D. L. Pulfrey},
  title = {Accurate, short series approximations to Fermi--Dirac integrals of
	order -1/2, 1/2, 1, 3/2, 2, 5/2, 3, and 7/2},
  journal = {Journal of Applied Physics},
  year = {1985},
  volume = {57},
  pages = {5271-5274},
  number = {12},
  note = {Be sure to check erratum (Halen1986)},
  doi = {10.1063/1.335269},
  file = {Halen1985.pdf:Halen1985.pdf:PDF},
  keywords = {SERIES EXPANSION; INTEGRALS; ACCURACY; ERRORS; FERMI STATISTICS},
  owner = {mrterry},
  publisher = {AIP},
  timestamp = {2008.01.24},
  url = {http://link.aip.org/link/?JAP/57/5271/1}
}

@ELECTRONIC{doxygen,
  author = {Dimitri van Heesch},
  title = {Doxygen},
  url = {http://www.stack.nl/~dimitri/doxygen/},
  owner = {mrterry},
  timestamp = {2010.07.19}
}

@ARTICLE{heltemes05,
  author = {T. A. Heltemes and G. A. Moses and J. F. Santarius},
  title = {Analysis of an Improved Fusion Reaction Rate Model for Use in Fusion
	Plasma Simulations},
  journal = {Univerisity of Wisconsin Fusion Design Memo},
  year = {2005},
  volume = {UWFDM-1268},
  pages = {1-12},
  file = {heltemes05.pdf:heltemes05.pdf:PDF}
}

@BOOK{paraview,
  title = {The {ParaView} Guide: A Parallel Visualization Application},
  publisher = {Kitware},
  year = {2004},
  author = {Henderson, Amy},
  pages = {340},
  month = nov,
  citeulike-article-id = {4375994},
  posted-at = {2009-04-22 19:21:00},
  priority = {2}
}

@ARTICLE{Ho1994,
  author = {D.D.-M. Ho and J.D. Lindl and M. Tabak},
  title = {Radiation converter physics and a method for obtaining the upper
	limit for gain in heavy ion fusion},
  journal = {Nuclear Fusion},
  year = {1994},
  volume = {34},
  pages = {1081},
  number = {8},
  abstract = {Converting the kinetic energy of heavy ion beams into radiation energy
	at high efficiency is important for heavy ion fusion. High conversion
	efficiency can be achieved if the radiating material consists mainly
	of a low Z element, for example, beryllium, mixed with a small amount
	of high Z element, for example, lead. For stopping incoming beams
	with a given energy, low Z material has higher stopping power and
	hence has less total internal energy than a high Z material. A high
	Z material is used for efficient radiation; the exact amount used
	is determined by the requirement that the Planck mean free path is
	approximately equal to the dimension of the radiation converter.
	Too much high Z material would hence prevent radiation from escaping
	from the interior region of the radiating material. To reduce the
	hydrodynamic loss in the radial direction, the radiating material
	is placed inside a casing made of high Z material. Calculations show
	that the energy absorbed by the casing is tolerable and that the
	interface between the casing and the radiating material is almost
	stationary. Various scaling laws for the converter are developed.
	Simulations with the LASNEX hydrodynamic code show that carefully
	designed converters can have conversion efficiencies as high as 70%
	(80%) for incoming beams with 10 GeV (5 GeV) energy. Because the
	converters have high efficiency and ion range shortening in beryllium
	is not substantial, range shortening is not a major issue. Once the
	diagram for the conversion efficiency versus the converter radius
	is obtained for various beam ion energies, the trajectory is located
	on this diagram that gives the upper limit for conversion efficiency
	(and hence for gain) while satisfying the engineering limit of the
	quadrupole pole-tip magnetic fields of the final-focusing system
	for heavy ion beams (for ballistic transport through a hard-vacuum
	reactor chamber). Finally, converter configurations are presented
	that can deflect the direction of radiation, thereby eliminating
	the need for ion beam bending},
  file = {:Ho1994.pdf:PDF},
  url = {http://stacks.iop.org/0029-5515/34/i=8/a=I03}
}

@ARTICLE{Hogan2001,
  author = {W. J. Hogan and E. I. Moses and E. E. Warner and M. S. Sorem and
	J. M. Soures},
  title = {The {N}ational {I}gnition {F}acility},
  journal = {Nuclear Fusion},
  year = {2001},
  volume = {41},
  pages = {567-573},
  owner = {mrterry},
  timestamp = {2009.04.14}
}

@ARTICLE{Honda1963,
  author = {Naobumi Honda and Osamu Aono and Taro Kihara},
  title = {Fluctuations in a Plasma III: Effect of the Magnetic Field on the
	Stopping Power},
  journal = {Journal of the Physical Society of Japan},
  year = {1963},
  volume = {18},
  pages = {256-260},
  owner = {mrterry},
  timestamp = {2009.04.22}
}

@BOOKLET{NRLpp06,
  title = {{NRL} Plasma Formulary},
  author = {J. D. Huba},
  year = {2007}
}

@ARTICLE{Hubbard1961,
  author = {Hubbard, J},
  title = {The Friction and Diffusion Coefficients of the Fokker-Planck Equation
	in a Plasma},
  journal = {Proceedings of the Royal Society of London. Series A, Mathematical
	and Physical Sciences,},
  year = {1961},
  volume = {260},
  pages = {114-126},
  file = {Hubbard1961.pdf:Hubbard1961.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.04.03},
  url = {http://links.jstor.org/sici?sici=0080-4630%2819610207%29260%3A1300%3C114%3ATFADCO%3E2.0.CO%3B2-S}
}

@ARTICLE{Hubbard1961a,
  author = {Hubbard, J},
  title = {The Friction and Diffusion Coefficients of the Fokker-Planck Equation
	in a Plasma.
	
	II},
  journal = {Proceedings of the Royal Society of London. Series A, Mathematical
	and Physical Sciences,},
  year = {1961},
  volume = {261},
  pages = {371-387},
  file = {Hubbard1961a.pdf:Hubbard1961a.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.04.03}
}

@ARTICLE{Hubbard1955,
  author = {J Hubbard},
  title = {On the Interaction of Electrons in Metals},
  journal = {Proceedings of the Physical Society. Section A},
  year = {1955},
  volume = {68},
  pages = {441-443},
  number = {5},
  doi = {10.1088/0370-1298/68/5/413},
  file = {Hubbard1955.pdf:Hubbard1955.pdf:PDF},
  url = {http://stacks.iop.org/0370-1298/68/441}
}

@BOOK{Hunt1999,
  title = {The Pragmatic Programmer: From Journeyman to Master},
  publisher = {Addison-Wesley Professional},
  year = {1999},
  author = {Andrew Hunt and David Thomas},
  owner = {mrterry},
  timestamp = {2010.06.05}
}

@ARTICLE{matplotlib,
  author = {John D. Hunter},
  title = {Matplotlib: A 2D Graphics Environment},
  journal = {Computing in Science and Engineering},
  year = {2007},
  volume = {9},
  pages = {90-95},
  address = {Los Alamitos, CA, USA},
  doi = {http://doi.ieeecomputersociety.org/10.1109/MCSE.2007.55},
  issn = {1521-9615},
  publisher = {IEEE Computer Society}
}

@BOOK{Ichimaru1992,
  title = {Statistical Plasma Physics I: Basic Principles},
  publisher = {Addison-Wesley Publishing Company},
  year = {1992},
  editor = {David Pines},
  author = {Ichimaru, Setsuo},
  owner = {mrterry},
  timestamp = {2009.04.19}
}

@BOOK{Ichimaru1986,
  title = {Plasma Physics: An Introduction to Statistical Physics of Charged
	Particles},
  publisher = {The Benjamin/Cummings Publishing Company, Inc},
  year = {1986},
  editor = {David Pines},
  author = {Ichimaru, Setsuo},
  owner = {mrterry},
  timestamp = {2009.04.19}
}

@BOOK{Ichimaru1994,
  title = {Statistical Plasma Physics II: Condensed Plasmas},
  publisher = {Addison-Wesley Publishing Company},
  year = {1994},
  author = {Ichimaru, Setsuo},
  owner = {mrterry},
  timestamp = {2009.04.19}
}

@BOOK{jackson,
  title = {Classical Electrodynamics, 2nd Ed.},
  publisher = {Wiley},
  year = {1975},
  author = {John David Jackson}
}

@MANUAL{Jython,
  title = {Jython 2.5.1 Documentation},
  author = {Josh Juneau},
  organization = {Jython Project},
  edition = {2.5.1},
  month = {August},
  year = {2010},
  owner = {mrterry},
  timestamp = {2010.08.04},
  url = {http://www.jython.org/docs/}
}

@ARTICLE{Kawata2009,
  author = {S. Kawata and Y. Iizuka and Y. Kodera and A.I. Ogoyski and T. Kikuchi},
  title = {Robust fuel target in heavy ion inertial fusion},
  journal = {Nuclear Instruments and Methods in Physics Research Section A: Accelerators,
	Spectrometers, Detectors and Associated Equipment},
  year = {2009},
  volume = {606},
  pages = {152 - 156},
  number = {1-2},
  note = {Heavy Ion Inertial Fusion - Proceedings of the 17th International
	Symposium on Heavy Ion Inertial Fusion},
  abstract = {Uniformity of heavy ion beam (HIB) illumination is one of the key
	issues in HIB inertial confinement fusion (HIF): deviation from fuel
	implosion symmetry should be less than a few percent in order to
	compress a fuel sufficiently and release fusion energy effectively.
	In this paper, a new mitigation method of the Rayleigh-Taylor (R-T)
	instability growth is presented in order to make a HIF target robust
	against a non-uniform implosion. In this study a new mitigation method
	of R-T instability growth is proposed based on an oscillating perturbed
	acceleration, which can be realized by a rotating or oscillating
	HIB illumination onto a fuel pellet. The R-T instability analyses
	and fluid simulations demonstrate that the oscillating acceleration
	reduces the R-T instability growth significantly. In this paper a
	baseline steady acceleration g0 is perturbed by a perturbed oscillating
	acceleration [delta]g, which is spatially non-uniform and oscillates
	in time (g0[not double greater-than sign][delta]g). An example result
	shows 84% reduction of the R-T instability growth.},
  doi = {DOI: 10.1016/j.nima.2009.03.188},
  file = {:Kawata2009.pdf:PDF},
  issn = {0168-9002},
  keywords = {Heavy ion beam},
  url = {http://www.sciencedirect.com/science/article/B6TJM-4VY2C3C-3/2/bffde61431524a50c54e4a3399818726}
}

@ARTICLE{Kawata2010,
  author = {S Kawata and T Kodera and Y Hisatomi and A I Ogoyski and S Koseki
	and D Barada},
  title = {Rayleigh-Taylor instability growth control by an oscillating acceleration
	in heavy ion inertial fusion},
  journal = {Journal of Physics: Conference Series},
  year = {2010},
  volume = {244},
  pages = {022003},
  number = {2},
  abstract = {Uniformity of heavy ion beam (HIB) illumination is one of key issues
	in HIB inertial confinement fusion (HIF) in order to compress a fuel
	sufficiently and release fusion energy effectively. In this paper
	a new mitigation method of the Rayleigh-Taylor (R-T) instability
	growth is presented to make a HIF target robust against a non-uniform
	implosion. In this study a new mitigation method of the R-T instability
	growth is proposed based on an oscillating perturbed acceleration,
	which can be realized by a rotation or oscillation of the HIB illumination
	axis onto a fuel pellet. The R-T instability analyses and fluid simulations
	demonstrate that the oscillating acceleration reduces the R-T instability
	growth significantly. In this paper a baseline steady acceleration
	g 0 is perturbed by a perturbed oscillating acceleration ?¥ g , which
	is spatially non-uniform and oscillates in time ( g 0 >> ?¥ g ).
	An example result shows an 84% reduction of the R-T instability growth.
	In the analytical work two stratified inviscid fluids are treated
	under the perturbed oscillating acceleration. The linear analysis
	shows that the R-T instability growth rate does not change from the
	standard expression of ??. However, the R-T instability growth is
	strongly affected and mitigated by the oscillating acceleration;
	The transverse velocity of w is derived at the interface of the two
	stratified fluids. The R-T instability is induced by ?¥ g . The result
	presents that the perturbed oscillating acceleration reduces the
	R-T instability growth significantly depending on the magnitude of
	the HIB oscillation frequency.},
  file = {:Kawata2010.pdf:PDF},
  url = {http://stacks.iop.org/1742-6596/244/i=2/a=022003}
}

@ARTICLE{Kawata2008,
  author = {S Kawata and K Miyazawa and A I Ogoyskii and T Kikuchi and Y Akasaka
	and Y Iizuka},
  title = {Direct-indirect hybrid mode implosion in heavy ion inertial fusion},
  journal = {Journal of Physics: Conference Series},
  year = {2008},
  volume = {112},
  pages = {032028},
  number = {3},
  abstract = {A direct-indirect hybrid implosion mode is proposed and discussed
	in heavy ion beam (HIB) inertial confinement fusion (HIF) in order
	to release sufficient fusion energy in a robust manner. On the other
	hand, the HIB illumination non-uniformity depends strongly on a target
	displacement dz from the centre of a fusion reactor chamber. In a
	direct-driven implosion mode, dz of ~ 20 ?ºm was tolerable, and in
	an indirect-implosion mode, dz of ~ 100 ?ºm was allowable. In the
	direct-indirect mixture mode target, a low-density foam layer is
	inserted, and the radiation energy is confined in the foam layer.
	In the foam layer the radiation transport is expected to smooth the
	HIB illumination non-uniformity in the lateral direction. Two-dimensional
	implosion simulations are performed, and show that the HIB illumination
	non-uniformity is well smoothed in the direct-indirect hybrid-mode
	target. Our simulation results present that a large pellet displacement
	of ~ a few hundred ?ºm is allowed in order to obtain a sufficient
	fusion energy output in HIF.},
  file = {:Kawata2008.pdf:PDF},
  url = {http://stacks.iop.org/1742-6596/112/i=3/a=032028}
}

@ARTICLE{kawrakow98,
  author = {Iwan Kawrakow and Alex F. Bielajew},
  title = {On the representation of electron multiple elastic-scattering distributions
	for Monte Carlo calculations},
  journal = {Nuclear Instruments and Methods in Physics Research B},
  year = {1998},
  volume = {134},
  pages = {325-336},
  doi = {10.1016/S0168-583X(97)00723-4},
  file = {kawrakow98.pdf:kawrakow98.pdf:PDF}
}

@ARTICLE{Kidder1979,
  author = {Kidder, R. E.},
  title = {Laser-Driven Isentropic Hollow-Shell Implosions: The Problem of Ignition},
  journal = {Nuclear Fusion},
  year = {1979},
  volume = {19},
  pages = {223-234},
  file = {Kidder1979.pdf:Kidder1979.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.02.29}
}

@ARTICLE{Kidder1976,
  author = {Kidder, R. E.},
  title = {Laser-Driven Compression of Hollow Shells: Power Requirements and
	Stability Limitations},
  journal = {Nuclear Fusion},
  year = {1976},
  volume = {16},
  pages = {3-14},
  file = {Kidder1976.pdf:Kidder1976.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.02.29}
}

@ARTICLE{Kidder1976a,
  author = {Kidder, R. E.},
  title = {Energy Gain of Laser-Compressed Pellets: A Simple Model Calculation},
  journal = {Nuclear Fusion},
  year = {1976},
  volume = {16},
  pages = {405-408},
  file = {Kidder1976a.pdf:Kidder1976a.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.02.29}
}

@ARTICLE{Kidder1974,
  author = {R. E. Kidder},
  title = {Theory of Homogeneous Isentropic Compression and Its Application
	to Laser Fusion},
  journal = {Nuclear Fusion},
  year = {1974},
  volume = {14},
  pages = {53-60},
  file = {Kidder1974.pdf:Kidder1974.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.02.29}
}

@ARTICLE{Kidder1974a,
  author = {Kidder, R. E.},
  title = {Laser Compression of Matter: Optical Power and Energy Requirements},
  journal = {Nuclear Fusion},
  year = {1974},
  volume = {14},
  pages = {797-803},
  file = {Kidder1974a.pdf:Kidder1974a.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.02.29}
}

@ARTICLE{Kihara1963,
  author = {Taro Kihara and Osamu Aono},
  title = {Unified Theory of Relaxations in Plasmas I: Basic Theorem},
  journal = {Journal of the Physical Society of Japan},
  year = {1963},
  volume = {18},
  pages = {837-851},
  doi = {10.1143/JPSJ.18.837},
  file = {Kihara1963.pdf:Kihara1963.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.04.03}
}

@ARTICLE{Klimo2011,
  author = {O. Klimo and V. T. Tikhonchuk and X. Ribeyre and G. Schurtz and C.
	Riconda and S. Weber and J. Limpouch},
  title = {Laser plasma interaction studies in the context of shock ignition---Transition
	from collisional to collisionless absorption},
  journal = {Physics of Plasmas},
  year = {2011},
  volume = {18},
  pages = {082709},
  number = {8},
  eid = {082709},
  doi = {10.1063/1.3625264},
  file = {:Klimo2011.pdf:PDF},
  keywords = {plasma collision processes; plasma light propagation; plasma shock
	waves; plasma simulation; plasma transport processes},
  numpages = {12},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/18/082709/1}
}

@ARTICLE{Knuth1974,
  author = {Knuth, Donald E.},
  title = {Structured Programming with go to Statements},
  journal = {ACM Comput. Surv.},
  year = {1974},
  volume = {6},
  pages = {261--301},
  number = {4},
  month = dec,
  acmid = {356640},
  address = {New York, NY, USA},
  doi = {10.1145/356635.356640},
  issn = {0360-0300},
  issue_date = {Dec. 1974},
  numpages = {41},
  publisher = {ACM},
  url = {http://doi.acm.org/10.1145/356635.356640}
}

@ARTICLE{Koniges2010,
  author = {A E Koniges and N D Masters and A C Fisher and R W Anderson and D
	C Eder and T B Kaiser and D S Bailey and B Gunney and P Wang and
	B Brown and K Fisher and F Hansen and B R Maddox and D J Benson and
	M Meyers and A Geille},
  title = {ALE-AMR: A new 3D multi-physics code for modeling laser/target effects},
  journal = {Journal of Physics: Conference Series},
  year = {2010},
  volume = {244},
  pages = {032019},
  number = {3},
  abstract = {We have developed a new 3D multi-physics multi-material code, ALE-AMR,
	for modeling laser/target effects including debris/shrapnel generation.
	The code combines Arbitrary Lagrangian Eulerian (ALE) hydrodynamics
	with Adaptive Mesh Refinement (AMR) to connect the continuum to microstructural
	regimes. The code is unique in its ability to model hot radiating
	plasmas and cold fragmenting solids. New numerical techniques were
	developed for many of the physics packages to work efficiency on
	a dynamically moving and adapting mesh. A flexible strength/failure
	framework allows for pluggable material models. Material history
	arrays are used to store persistent data required by the material
	models, for instance, the level of accumulated damage or the evolving
	yield stress in J2 plasticity models. We model ductile metals as
	well as brittle materials such as Si, Be, and B4C. We use interface
	reconstruction based on volume fractions of the material components
	within mixed zones and reconstruct interfaces as needed. This interface
	reconstruction model is also used for void coalescence and fragmentation.
	The AMR framework allows for hierarchical material modeling (HMM)
	with different material models at different levels of refinement.
	Laser rays are propagated through a virtual composite mesh consisting
	of the finest resolution representation of the modeled space. A new
	2nd order accurate diffusion solver has been implemented for the
	thermal conduction and radiation transport packages. The code is
	validated using laser and x-ray driven spall experiments in the US
	and France. We present an overview of the code and simulation results.},
  url = {http://stacks.iop.org/1742-6596/244/i=3/a=032019}
}

@ARTICLE{Kramers1947,
  author = {H. A. Kramers},
  title = {The stopping power of a metal for alpha-particles},
  journal = {Physica},
  year = {1947},
  volume = {13},
  pages = {401-412},
  doi = {10.1016/0031-8914(47)90014-1},
  owner = {mterry},
  timestamp = {2007.10.30}
}

@ARTICLE{Lafon2010,
  author = {M. Lafon and X. Ribeyre and G. Schurtz},
  title = {Gain curves and hydrodynamic modeling for shock ignition},
  journal = {Physics of Plasmas},
  year = {2010},
  volume = {17},
  pages = {052704},
  number = {5},
  eid = {052704},
  doi = {10.1063/1.3407623},
  keywords = {explosions; fusion reactor fuel; fusion reactor ignition; plasma shock
	waves},
  numpages = {14},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/17/052704/1}
}

@INCOLLECTION{Landau1936english,
  author = {L. D. Landau},
  title = {The Transport Equation in the Case of {C}oulomb Interactions},
  booktitle = {The Collected Papers of L. D. Landau},
  publisher = {Gordon and Breach, Science Publishers},
  year = {1965},
  editor = {D. ter Haar},
  pages = {163-170},
  edition = {2},
  abstract = {A transport equation is derived for a system consisting of charged
	particles taking their interactions into account. The order of magnitude
	of the mean free path of the particles in such a system is determined.
	The rate at which the temperatures of the ions and electrons in the
	plasma become equal is evaluated.},
  file = {Landau1936english.pdf:Landau1936english.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.03.05}
}

@ARTICLE{Landau1936,
  author = {Landau, L. D.},
  title = {Die kinetishe Gleichung fur den Fall Coulombscher Wechselwirkung},
  journal = {Phys. Z. Sowjet},
  year = {1936},
  volume = {10},
  pages = {154},
  file = {:Landau1936english.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.03.05}
}

@ARTICLE{larsen92,
  author = {Edward W. Larsen},
  title = {A Theoretical Derivation of the Condensed History Algorithm},
  journal = {Annals of Nuclear Energy},
  year = {1992},
  volume = {19},
  pages = {701-714},
  doi = {10.1016/0306-4549(92)90013-2}
}

@ARTICLE{Lenard1960,
  author = {Andrew Lenard},
  title = {On {B}ogoliubov's kinetic equation for a spatially homogeneous plasma},
  journal = {Annals of Physics},
  year = {1960},
  volume = {10},
  pages = {390-400},
  doi = {10.1016/0003-4916(60)90003-8},
  file = {Lenard1960.pdf:Lenard1960.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.03.28}
}

@ARTICLE{li06,
  author = {C. K. Li and R. D. Petrasso},
  title = {Stopping, straggling, and blooming of directed energetic electrons
	in hydrogenic and arbitrary-Z plasmas},
  journal = {Phys. Rev. E},
  year = {2006},
  volume = {73},
  pages = {016402},
  number = {1},
  eid = {016402},
  doi = {10.1103/PhysRevE.73.016402},
  file = {li06.pdf:li06.pdf:PDF},
  keywords = {plasma collision processes; plasma properties},
  numpages = {5},
  publisher = {APS},
  url = {http://link.aps.org/abstract/PRE/v73/e016402}
}

@ARTICLE{li95,
  author = {Chi-Kang Li and Richard D. Petrasso},
  title = {Effects of Scattering upon Energetic Ion Energy Loss in Plasmas},
  journal = {Physics of Plasmas},
  year = {1995},
  volume = {2},
  pages = {2460-2464},
  doi = {10.1063/1.871271},
  file = {li95.pdf:li95.pdf:PDF}
}

@ARTICLE{li93_fp,
  author = {Li, Chi-Kang and Petrasso, Richard D.},
  title = {{F}okker-{P}lanck equation for moderately coupled plasmas},
  journal = {Phys. Rev. Lett.},
  year = {1993},
  volume = {70},
  pages = {3063--3066},
  number = {20},
  month = {May},
  doi = {10.1103/PhysRevLett.70.3063},
  file = {li93_fp.pdf:li93_fp.pdf:PDF},
  numpages = {3},
  publisher = {American Physical Society}
}

@ARTICLE{li93_icf,
  author = {Li, Chi-Kang and Petrasso, Richard D.},
  title = {Charged-particle stopping powers in inertial confinement fusion plasmas},
  journal = {Phys. Rev. Lett.},
  year = {1993},
  volume = {70},
  pages = {3059--3062},
  number = {20},
  month = {May},
  doi = {10.1103/PhysRevLett.70.3059},
  file = {li93_icf.pdf:li93_icf.pdf:PDF},
  numpages = {3},
  publisher = {American Physical Society}
}

@BOOK{Lifshitz1981,
  title = {Physical Kinetics},
  publisher = {Butterworth-Heinemann},
  year = {1981},
  author = {Lifshitz, E. M. and Pitaevskii, L. P.},
  volume = {10},
  series = {Course of Theoretical Physics},
  owner = {mrterry},
  timestamp = {2008.04.16}
}

@ARTICLE{Lindhard1963,
  author = {J. Lindhard and V. Nielsen and M. Scharff and P.?V. Thomsen},
  journal = {K. Dan. Vidensk. Selsk. Mat. Fys. Medd},
  year = {1963},
  volume = {33},
  owner = {mrterry},
  timestamp = {2009.04.22}
}

@ARTICLE{Lindhard1961,
  author = {Lindhard, J. and Scharff, M.},
  title = {Energy Dissipation by Ions in the kev Region},
  journal = {Phys. Rev.},
  year = {1961},
  volume = {124},
  pages = {128--130},
  number = {1},
  month = {Oct},
  doi = {10.1103/PhysRev.124.128},
  file = {Lindhard1961.pdf:Lindhard1961.pdf:PDF},
  numpages = {2},
  publisher = {American Physical Society}
}

@ARTICLE{Lindl1985,
  author = {Lindl,J. D. and Mark,J. W-K.},
  title = {Recent Livermore estimates on the energy gain of cryogenic single-shell
	ion beam targets},
  journal = {Laser and Particle Beams},
  year = {1985},
  volume = {3},
  pages = {37-40},
  number = {01},
  abstract = { ABSTRACT Our recent estimates are that the energy-gains for cryogenic
	single-shell targets are close to those of similar double-shelled
	targets. However, the peak-power requirements for single-shell targets
	are still about a factor of two higher. },
  doi = {10.1017/S0263034600001245},
  eprint = {http://journals.cambridge.org/article_S0263034600001245},
  file = {:Lindl1985.pdf:PDF},
  url = {http://dx.doi.org/10.1017/S0263034600001245}
}

@INPROCEEDINGS{Litzkow1988,
  author = {Michael Litzkow and Miron Livny and Matthew Mutka},
  title = {{C}ondor - A Hunter of Idle Workstations},
  booktitle = {Proceedings of the 8th International Conference of Distributed Computing
	Systems},
  year = {1988},
  month = {June},
  file = {Litzkow1988.pdf:Litzkow1988.pdf:PDF}
}

@ARTICLE{Logan2008,
  author = {B. G. Logan and L. J. Perkins and J. J. Barnard},
  title = {Direct drive heavy-ion-beam inertial fusion at high coupling efficiency},
  journal = {Physics of Plasmas},
  year = {2008},
  volume = {15},
  pages = {072701},
  number = {7},
  eid = {072701},
  doi = {10.1063/1.2950303},
  file = {Logan2008.pdf:Logan2008.pdf:PDF},
  keywords = {explosions; plasma-beam interactions; Rayleigh-Taylor instability},
  numpages = {7},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/15/072701/1}
}

@ARTICLE{Long1987,
  author = {Long, Keith A. and Tahir, Naeem A.},
  title = {Range shortening, radiation transport, and Rayleigh-Taylor instability
	phenomena in ion-beam-driven inertial-fusion-reactor-size targets:
	Implosion, ignition, and burn phases},
  journal = {Phys. Rev. A},
  year = {1987},
  volume = {35},
  pages = {2631--2659},
  number = {6},
  month = {Mar},
  doi = {10.1103/PhysRevA.35.2631},
  file = {Long1987.pdf:Long1987.pdf:PDF},
  numpages = {28},
  publisher = {American Physical Society}
}

@BOOK{Longmire1963,
  title = {Elementary Plasma Physics},
  publisher = {Interscience Publishers, Inc.},
  year = {1963},
  author = {Conrad L. Longmire},
  owner = {mrterry},
  timestamp = {2008.02.28}
}

@ARTICLE{Luke1971,
  author = {Yudell L. Luke},
  title = {Rational Approximations for the Logarithmic Derivative of the Gamma
	Function},
  journal = {Applicable Analysis},
  year = {1971},
  volume = {1},
  pages = {65-73},
  owner = {mrterry},
  timestamp = {2008.11.05}
}

@ARTICLE{MacFarlane1995,
  author = {J.J. MacFarlane and G.A. Moses and R.R. Peterson},
  title = {BUCKY-1 - A 1-D Radiation Hydrodynamics Code for Simulating Inertial
	Confinement Fusion High Energy Density Plasmas},
  journal = {Univerisity of Wisconsin Fusion Design Memo},
  year = {1995},
  owner = {mrterry},
  timestamp = {2010.08.03}
}

@ARTICLE{MacLeod1998,
  author = {Allan J. MacLeod},
  title = {Algorithm 779: {F}ermi-{D}irac functions of order -1/2, 1/2, 3/2,
	5/2},
  journal = {ACM Trans. Math. Softw.},
  year = {1998},
  volume = {24},
  pages = {1--12},
  number = {1},
  address = {New York, NY, USA},
  doi = {http://doi.acm.org/10.1145/285861.285862},
  file = {MacLeod1998.pdf:MacLeod1998.pdf:PDF},
  issn = {0098-3500},
  owner = {mrterry},
  publisher = {ACM},
  timestamp = {2008.05.28}
}

@ARTICLE{Magelssen1984,
  author = {G.R. Magelssen},
  title = {Targets driven by dual-energy heavy ions},
  journal = {Nuclear Fusion},
  year = {1984},
  volume = {24},
  pages = {1527},
  number = {12},
  abstract = {Target designs that utilize heavy-ion beams with two substantially
	different particle energies are presented. Low-energy ions of moderate
	power are used to directly drive a spherical-shell target that is
	cryogenically layered with a deuterium-tritium (DT) mixture. The
	purpose of this first pulse is to compress the DT fuel and tamper;
	compressions of a hundred to a few hundred times solid density appear
	possible. Following compression the target is irradiated with a high-particle
	energy and high-power pulse. The main purpose of the second pulse
	is to bring the central DT region to ignition. Additional compression
	of no more than 10 is needed. For targets with a low-Z pusher, gains
	greater than a hundred are possible with an ignition pulse of 1000
	TW and a heavy-ion particle energy of 40 GeV. Pulse requirements,
	finite focusing effects, and symmetry requirements are discussed.},
  file = {Magelssen1984.pdf:Magelssen1984.pdf:PDF},
  url = {http://stacks.iop.org/0029-5515/24/i=12/a=001}
}

@ARTICLE{Magelssen1986,
  author = {G. R. Magelssen},
  title = {Gain scaling laws for HIF},
  journal = {AIP Conference Proceedings},
  year = {1986},
  volume = {152},
  pages = {428-434},
  number = {1},
  doi = {10.1063/1.36298},
  file = {:Magelssen1986.pdf:PDF},
  keywords = {ION BEAM FUSION REACTORS; SCALING LAWS; ENERGY CONVERSION; GAIN; BEAM
	DYNAMICS; RADIATION TRANSPORT; NUMERICAL DATA},
  publisher = {AIP},
  url = {http://link.aip.org/link/?APC/152/428/1}
}

@ARTICLE{Marinak2001,
  author = {M. M. Marinak and G. D. Kerbel and N. A. Gentile and O. Jones and
	D. Munro and S. Pollaine and T. R. Dittrich and S. W. Haan},
  title = {Three-dimensional HYDRA simulations of National Ignition Facility
	targets},
  journal = {Physics of Plasmas},
  year = {2001},
  volume = {8},
  pages = {2275-2280},
  number = {5},
  doi = {10.1063/1.1356740},
  file = {:/Users/terry10/Marinak2001.pdf:PDF},
  keywords = {fusion reactor ignition; laser fusion; plasma simulation; plasma instability},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/8/2275/1}
}

@ARTICLE{Marinak1996,
  author = {M. M. Marinak and R. E. Tipton and O. L. Landen and T. J. Murphy
	and P. Amendt and S. W. Haan and S. P. Hatchett and C. J. Keane and
	R. McEachern and R. Wallace},
  title = {Three-dimensional simulations of Nova high growth factor capsule
	implosion experiments},
  journal = {Physics of Plasmas},
  year = {1996},
  volume = {3},
  pages = {2070-2076},
  number = {5},
  doi = {10.1063/1.872004},
  file = {:Marinak1996.pdf:PDF},
  keywords = {NOVA FACILITY; LASER FUSION REACTORS; IMPLOSIONS; PLASMA SIMULATION;
	HOT SPOTS; ICF DEVICES; RAYLEIGHTAYLOR INSTABILITY; CAPSULES},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/3/2070/1}
}

@ARTICLE{Mark1986,
  author = {James W. -K. Mark},
  title = {Near spherical illumination of ion-beam and laser targets},
  journal = {Physics Letters A},
  year = {1986},
  volume = {114},
  pages = {458 - 464},
  number = {8-9},
  abstract = {A procedure is developed for reducing energy-deposition asymmetry
	in spherical targets driven directly by ion or laser beams. This
	work is part of a strategy for achieving illumination symmetry in
	such targets, which is proposed as an alternative to those in the
	literature. This strategy allows an axially symmetric placement of
	beamlets, which would be convenient for some driver or reactor scenarios.
	It also allows the use of beam currents or energy fluxes and beam
	transverse profiles to help reduce deposition asymmetry with fewer
	beamlets. In the ideal limit of thin deposition layers and controlled
	beam profiles, at most six beamlets are needed for target symmetry.},
  doi = {DOI: 10.1016/0375-9601(86)90694-8},
  file = {:Mark1986.pdf:PDF},
  issn = {0375-9601},
  url = {http://www.sciencedirect.com/science/article/B6TVM-46VPYW4-2Y/2/74cce08510e484cec631309c765c5935}
}

@ARTICLE{Mark1991,
  author = {Mark,James W.-K.},
  title = {Recent Livermore research on ion beam fusion targets: Utilization
	of direct-drive efficiency during optimization of symmetry and utilization
	of polarized DT fuel},
  journal = {Laser and Particle Beams},
  year = {1991},
  volume = {9},
  pages = {713-723},
  number = {03},
  abstract = { ABSTRACT We investigated several examples of ion beam targets that
	utilize the energy efficiency of direct drive while optimizing on
	the symmetry requirements. Heavy-ion beams of charge state Z 10 GeV
	have 15&#8211;20 m bending radii with 3.5-T fields. Beams like these
	could be used with targets involving direct drive. Control of asymmetries
	in direct-drive ion beam targets depends on control of the effects
	of residual target asymmetries after an appropriate illumination
	scheme has been adopted. In this paper, we outline results of our
	investigations into ion beam target concepts in which the effects
	of residual asymmetries are ameliorated. The beams are placed according
	to our axially symmetric Gaussian-quadrature illumination scheme
	(Mark 1986). The targets survive the effects of residual asymmetries
	in our recent 2-D hydrodynamic simulations. We also briefly discuss
	the additional positive effects of polarized DT fuel on ion beam
	targets. },
  doi = {10.1017/S0263034600003724},
  eprint = {http://journals.cambridge.org/article_S0263034600003724},
  url = {http://dx.doi.org/10.1017/S0263034600003724}
}

@ARTICLE{Marozas2006,
  author = {J. A. Marozas and F. J. Marshall and R. S. Craxton and I. V. Igumenshchev
	and S. Skupsky and M. J. Bonino and T. J. B. Collins and R. Epstein
	and V. Yu. Glebov and D. Jacobs-Perkins and J. P. Knauer and R. L.
	McCrory and P. W. McKenty and D. D. Meyerhofer and S. G. Noyes and
	P. B. Radha and T. C. Sangster and W. Seka and V. A. Smalyuk},
  title = {Polar-direct-drive simulations and experiments},
  journal = {Physics of Plasmas},
  year = {2006},
  volume = {13},
  pages = {056311},
  number = {5},
  eid = {056311},
  doi = {10.1063/1.2184949},
  file = {:Marozas2006.pdf:PDF},
  keywords = {laser fusion; fusion reactor design; fusion reactor targets; plasma
	simulation; plasma transport processes; plasma X-ray sources; explosions;
	fusion reactor instrumentation; plasma diagnostics},
  numpages = {8},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/13/056311/1}
}

@BOOK{matlab,
  title = {version 7.10.0 (R2010a)},
  publisher = {The MathWorks Inc.},
  year = {2010},
  author = {MATLAB},
  address = {Natick, Massachusetts}
}

@ARTICLE{Matzen1997,
  author = {Keith Matzen},
  title = {Z pinches as intense x-ray sources for high-energy density physics
	applications},
  journal = {Physics of Plasmas},
  year = {1997},
  volume = {4},
  pages = {1520-1527},
  doi = {10.1063/1.872323},
  file = {Matzen1997.pdf:Matzen1997.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.02.28}
}

@ARTICLE{May1969,
  author = {May, R. M.},
  title = {Energy loss by fast test ions in a plasma},
  journal = {Australian Journal of Physics},
  year = {1969},
  volume = {22},
  pages = {687},
  owner = {mrterry},
  timestamp = {2009.05.04}
}

@ARTICLE{May1970,
  author = {Robert M. May and N. F. Cramer},
  title = {Test Ion Energy Loss in a Plasma with a Magnetic Field},
  journal = {Physics of Fluids},
  year = {1970},
  volume = {13},
  pages = {1766-1770},
  doi = {10.1063/1.1693152},
  file = {May1970.pdf:May1970.pdf:PDF},
  owner = {mterry},
  timestamp = {2007.10.29}
}

@ARTICLE{maynard82,
  author = {Maynard, Gilles and Deutsch, Claude },
  title = {Energy loss and straggling of ions with any velocity in dense plasmas
	at any temperature},
  journal = {Phys. Rev. A},
  year = {1982},
  volume = {26},
  pages = {665--668},
  number = {1},
  month = {Jul},
  doi = {10.1103/PhysRevA.26.665},
  file = {maynard82.pdf:maynard82.pdf:PDF},
  numpages = {3}
}

@ARTICLE{McCrory2001,
  author = {R.L. McCrory and R.E. Bahr and R. Betti and T.R. Boehly and T.J.B.
	Collins and R.S. Craxton and J.A. Delettrez and W.R. Donaldson and
	R. Epstein and J. Frenje and V.Yu. Glebov and V.N. Goncharov and
	O.V. Gotchev and R.Q. Gram and D.R. Harding and D.G. Hicks and P.A.
	Jaanimagi and R.L. Keck and J.H. Kelly and J.P. Knauer and C.K. Li
	and S.J. Loucks and L.D. Lund and F.J. Marshall and P.W. McKenty
	and D.D. Meyerhofer and S.F.B. Morse and R.D. Petrasso and P.B. Radha
	and S.P. Regan and S. Roberts and F. Séguin and W. Seka and S. Skupsky
	and V.A. Smalyuk and C. Sorce and J.M. Soures and C. Stoeckl and
	R.P.J. Town and M.D. Wittman and B. Yaakobi and J.D. Zuegel},
  title = {{OMEGA} {ICF} experiments and preparation for direct drive ignition
	on {NIF}},
  journal = {Nuclear Fusion},
  year = {2001},
  volume = {41},
  pages = {1413},
  number = {10},
  abstract = {Direct drive laser fusion ignition experiments rely on detailed understanding
	and control of irradiation uniformity, the Rayleigh-Taylor instability
	and target fabrication. The Laboratory for Laser Energetics (LLE)
	is investigating various theoretical aspects of a direct drive National
	Ignition Facility (NIF) ignition target based on an `all-DT' design:
	a spherical target of ~3.4 mm diameter, with a 1-2 μm CH wall
	thickness and a DT ice layer of ~340 μm near the triple point of
	DT (~19 K). OMEGA experiments are designed to address the critical
	issues related to direct drive laser fusion and to provide the necessary
	data to validate the predictive capability of LLE computer codes.
	The cryogenic targets to be used on OMEGA are hydrodynamically equivalent
	to those planned for the NIF. The current experimental studies on
	OMEGA address the essential components of direct drive laser fusion:
	irradiation uniformity and laser imprinting, Rayleigh-Taylor growth
	and saturation, compressed core performance and shell-fuel mixing,
	laser-plasma interactions and their effect on target performance,
	and cryogenic target fabrication and handling.},
  url = {http://stacks.iop.org/0029-5515/41/i=10/a=309}
}

@ARTICLE{McCrory2008,
  author = {R. L. McCrory and D. D. Meyerhofer and R. Betti and R. S. Craxton
	and J. A. Delettrez and D. H. Edgell and V. Yu. Glebov and V. N.
	Goncharov and D. R. Harding and D. W. Jacobs-Perkins and J. P. Knauer
	and F. J. Marshall and P. W. McKenty and P. B. Radha and S. P. Regan
	and T. C. Sangster and W. Seka and R. W. Short and S. Skupsky and
	V. A. Smalyuk and J. M. Soures and C. Stoeckl and B. Yaakobi and
	D. Shvarts and J. A. Frenje and C. K. Li and R. D. Petrasso and F.
	H. Seguin},
  title = {Progress in direct-drive inertial confinement fusion},
  journal = {Physics of Plasmas},
  year = {2008},
  volume = {15},
  pages = {055503},
  number = {5},
  eid = {055503},
  doi = {10.1063/1.2837048},
  file = {McCrory2008.pdf:McCrory2008.pdf:PDF},
  keywords = {fusion reactors; plasma inertial confinement; plasma production by
	laser},
  numpages = {8},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/15/055503/1}
}

@ARTICLE{Meeker1981,
  author = {Meeker, D. J. and Bangerter, R. O.},
  title = {Tamped, split fuel-layer ion-beam target},
  journal = {UCRL},
  year = {1981},
  file = {:Meeker1981.pdf:PDF},
  owner = {terry10},
  timestamp = {2011.04.29}
}

@ARTICLE{mehlhorn81,
  author = {Thomas A. Mehlhorn},
  title = {A finite material temperature model for ion energy depostition in
	ion-driven inertial confinement fusion targets},
  journal = {Journal of Applied Physics},
  year = {1981},
  volume = {52},
  pages = {6522-6532},
  doi = {10.1063/1.328602},
  file = {mehlhorn81.pdf:mehlhorn81.pdf:PDF}
}

@ARTICLE{Metzler1984,
  author = {Metzler,N. and Meyer-Ter-Vehn,J.},
  title = {Target study for heavy ion beam fusion},
  journal = {Laser and Particle Beams},
  year = {1984},
  volume = {2},
  pages = {27-48},
  number = {01},
  abstract = { ABSTRACT Heavy ion beam driven implosion of multilayered, single-shell
	targets for inertial confinement fusion are investigated by ID-simulation.
	Features characteristic of heavy ion energy deposition are studied.
	The ion beam energy and the tamper/absorber configuration which give
	optimum hydrodynamic efficiency and fuel ignition are found for a
	reactor-size target. A comparison of different pulse shapes with
	and without prepulse is presented. Implosion by a single-box pulse
	is found to give superior hydrodynamic efficiency and spherical stability.
	In addition to these specific results, general features of ion driven
	implosions are discussed and a brief description of the target code
	MINIHY is given. },
  doi = {10.1017/S0263034600000604},
  eprint = {http://journals.cambridge.org/article_S0263034600000604},
  url = {http://dx.doi.org/10.1017/S0263034600000604}
}

@ARTICLE{Miller2004,
  author = {George H. Miller and Edward I. Moses and Craig R. Wuest},
  title = {The National Ignition Facility},
  journal = {Optical Engineering},
  year = {2004},
  volume = {43},
  pages = {2841-2853},
  number = {12},
  doi = {10.1117/1.1814767},
  keywords = {laser beams; ignition; laser fusion; high-speed optical techniques;
	optical harmonic generation},
  publisher = {SPIE},
  url = {http://link.aip.org/link/?JOE/43/2841/1}
}

@ARTICLE{Miyazawa2005,
  author = {K. Miyazawa and A. I. Ogoyski and S. Kawata and T. Someya and T.
	Kikuchi},
  title = {Robust heavy-ion-beam illumination against a direct-drive-pellet
	displacement in inertial confinement fusion},
  journal = {Physics of Plasmas},
  year = {2005},
  volume = {12},
  pages = {122702},
  number = {12},
  eid = {122702},
  doi = {10.1063/1.2140684},
  file = {Miyazawa2005.pdf:Miyazawa2005.pdf:PDF},
  keywords = {plasma inertial confinement; ion beams; plasma-beam interactions;
	explosions; fusion reactor fuel; fusion reactor reaction chamber;
	plasma simulation},
  numpages = {9},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/12/122702/1}
}

@BOOK{Montgomery1971,
  title = {Theory of Unmagnetized Plasma},
  publisher = {Gordon and Breach, Science Publishers},
  year = {1971},
  author = {David C. Montgomery},
  owner = {mrterry},
  timestamp = {2009.04.13}
}

@BOOK{Montgomery1964,
  title = {Plasma Kinetic Theory},
  publisher = {McGraw-Hill Book Company},
  year = {1964},
  editor = {William A. Nierenberg},
  author = {Montgomery, D. C. and Tidman, D. A.},
  owner = {mrterry},
  timestamp = {2008.04.03}
}

@ARTICLE{More1985,
  author = {R. M. More},
  title = {Pressure Ionization, Resonances, and the Continuity of Bound and
	Free States},
  journal = {Advances in Atomic and Molecular Physics},
  year = {1985},
  volume = {21},
  pages = {305-356},
  file = {More1985.pdf:More1985.pdf:PDF},
  owner = {mrterry},
  timestamp = {2009.02.04}
}

@ARTICLE{More1988,
  author = {R. M. More and K. H. Warren and D. A. Young and G. B. Zimmerman},
  title = {A new quotidian equation of state (QEOS) for hot dense matter},
  journal = {Physics of Fluids},
  year = {1988},
  volume = {31},
  pages = {3059-3078},
  number = {10},
  doi = {10.1063/1.866963},
  file = {More1988.pdf:More1988.pdf:PDF},
  keywords = {EQUATIONS OF STATE; HOT PLASMA; HYDRODYNAMICS; SIMULATION; THERMODYNAMICS;
	SHOCK WAVES; DENSE PLASMA},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PFL/31/3059/1}
}

@MISC{traits,
  author = {David C. Morrill and Janet M. Swisher},
  title = {Traits 3 User Manual},
  year = {2006},
  owner = {mrterry},
  timestamp = {2010.06.06},
  url = {http://code.enthought.com/projects/traits/}
}

@ARTICLE{Munro1995,
  author = {Munro, David H.},
  title = {Using the Yorick interpreted language},
  journal = {Comput. Phys.},
  year = {1995},
  volume = {9},
  pages = {609--615},
  number = {6},
  month = nov,
  acmid = {222292},
  address = {Woodbury, NY, USA},
  issn = {0894-1866},
  issue_date = {Nov./Dec. 1995},
  numpages = {7},
  publisher = {American Institute of Physics Inc.},
  url = {http://dl.acm.org/citation.cfm?id=222284.222292}
}

@ARTICLE{Munro2001,
  author = {David H. Munro and Peter M. Celliers and Gilbert W. Collins and David
	M. Gold and Luiz B. Da Silva and Steven W. Haan and Robert C. Cauble
	and Bruce A. Hammel and Warren W. Hsing},
  title = {Shock timing technique for the National Ignition Facility},
  journal = {The 42nd annual meeting of the division of plasma physics of the
	American Physical Society and the 10th international congress on
	plasma physics},
  year = {2001},
  volume = {8},
  pages = {2245-2250},
  number = {5},
  doi = {10.1063/1.1347037},
  keywords = {laser fusion; shock waves; fusion reactor targets; time measurement;
	plasma diagnostics; fusion reactor instrumentation},
  location = {Quebec City, Quebec (Canada)},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/8/2245/1}
}

@ARTICLE{Murakami1986,
  author = {Masakatsu Murakami and Katsunobu Nishihara},
  title = {Smoothing of Nonuniformity by X-ray Radiation in Cannonball Target},
  journal = {Japanese Journal of Applied Physics},
  year = {1986},
  volume = {25},
  pages = {242-247},
  number = {Part 1, No. 2},
  doi = {10.1143/JJAP.25.242},
  file = {:Murakami1986.pdf:PDF},
  numpages = {5},
  publisher = {The Japan Society of Applied Physics},
  url = {http://jjap.jsap.jp/link?JJAP/25/242/}
}

@ARTICLE{Nersisyan1998,
  author = {Nersisyan, H. B.},
  title = {Stopping of charged particles in a magnetized classical plasma},
  journal = {Phys. Rev. E},
  year = {1998},
  volume = {58},
  pages = {3686--3692},
  number = {3},
  month = {Sep},
  doi = {10.1103/PhysRevE.58.3686},
  file = {Nersisyan1998.pdf:Nersisyan1998.pdf:PDF},
  numpages = {6},
  owner = {mterry},
  timestamp = {2007.10.29}
}

@ARTICLE{Nersisyan1998a,
  author = {H. B. Nersisyan and C. Deutsch},
  title = {Correlated fast ion stopping in magnetized classical plasma},
  journal = {Physics Letters A},
  year = {1998},
  volume = {246},
  pages = {325-328},
  doi = {10.1016/S0375-9601(98)00523-4},
  file = {Nersisyan1998a.pdf:Nersisyan1998a.pdf:PDF},
  owner = {mterry},
  timestamp = {2007.10.29}
}

@ARTICLE{Nersisyan2000,
  author = {Nersisyan, H. B. and Walter, M. and Zwicknagel, G. },
  title = {Stopping power of ions in a magnetized two-temperature plasma},
  journal = {Phys. Rev. E},
  year = {2000},
  volume = {61},
  pages = {7022--7033},
  number = {6},
  month = {Jun},
  doi = {10.1103/PhysRevE.61.7022},
  file = {Nersisyan2000.pdf:Nersisyan2000.pdf:PDF},
  numpages = {11},
  owner = {mterry},
  timestamp = {2007.10.29}
}

@ARTICLE{Neufeld1955,
  author = {Neufeld, Jacob and Ritchie, R. H.},
  title = {Passage of Charged Particles through Plasma},
  journal = {Phys. Rev.},
  year = {1955},
  volume = {98},
  pages = {1632--1642},
  number = {6},
  month = {Jun},
  doi = {10.1103/PhysRev.98.1632},
  file = {Neufeld1955.pdf:Neufeld1955.pdf:PDF},
  numpages = {10},
  owner = {mterry},
  timestamp = {2007.10.30}
}

@BOOK{Nicholson1983,
  title = {Introduction to Plasma Theory},
  publisher = {John Wiley and Sons},
  year = {1983},
  author = {Nicholson, Dwight R.},
  owner = {mrterry},
  timestamp = {2009.04.16}
}

@ARTICLE{global-arrays,
  author = {Nieplocha, Jaroslaw and Harrison, Robert J. and Littlefield, Richard
	J.},
  title = {Global arrays: a nonuniform memory access programming model for high-performance
	computers},
  journal = {J. Supercomput.},
  year = {1996},
  volume = {10},
  pages = {169--189},
  number = {2},
  month = jun,
  acmid = {243182},
  address = {Hingham, MA, USA},
  issn = {0920-8542},
  issue_date = {June 1996},
  keywords = {Grand Challenges, NUMA architecture, computational chemistry, distributed
	arrays, global arrays, one-sided communication, parallel programming
	environments, parallel programming models, scientific computing,
	shared memory},
  numpages = {21},
  publisher = {Kluwer Academic Publishers},
  url = {http://dl.acm.org/citation.cfm?id=243179.243182}
}

@ARTICLE{Nuckolls1972,
  author = {Nuckolls, John and Wood, Lowell and Thiessen, Albert and Zimmerman,
	George},
  title = {Laswer Compression of Matter to Super-High Densities: Thermonuclear
	(CTR) Applications},
  journal = {Nature},
  year = {1972},
  volume = {239},
  pages = {139-142},
  file = {Nuckolls1972.pdf:Nuckolls1972.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.02.29}
}

@ARTICLE{Ogoyski2003,
  author = {A. I. Ogoyski and T. Someya and T. Sasaki and S. Kawata},
  title = {Heavy ion beam irradiation non-uniformity in inertial fusion},
  journal = {Physics Letters A},
  year = {2003},
  volume = {315},
  pages = {372 - 377},
  number = {5},
  abstract = {A non-uniformity of heavy ion beam irradiation onto a direct-driven
	fuel pellet in heavy ion fusion (HIF) is studied numerically. The
	energy deposition non-uniformity is investigated by several beam
	irradiation systems. The results demonstrate for the first time in
	HIF that the deposition non-uniformity can be reduced to low values,
	for example, less than 2% for a 32-beam irradiation system.},
  doi = {DOI: 10.1016/S0375-9601(03)01042-9},
  file = {:Ogoyski2003.pdf:PDF},
  issn = {0375-9601},
  keywords = {Heavy ion beam},
  url = {http://www.sciencedirect.com/science/article/B6TVM-496FBFH-2/2/a465e290916259cbb7274f621fb8b4bb}
}

@ARTICLE{numpyscipy,
  author = {Travis E. Oliphant},
  title = {Python for Scientific Computing},
  journal = {Computing in Science \& Engineering},
  year = {2007},
  volume = {9},
  pages = {90},
  owner = {mrterry},
  timestamp = {2010.06.10}
}

@MANUAL{Oliphant2006,
  title = {Guide to NumPy},
  author = {Oliphant, Travis E.},
  address = {Provo, UT},
  month = mar,
  year = {2006},
  institution = {Brigham Young University},
  keywords = {numpy},
  url = {http://www.tramy.us/}
}

@ARTICLE{Ordonez1994,
  author = {C. A. Ordonez and M. I. Molina},
  title = {Evaluation of the Coulomb logarithm using cutoff and screened Coulomb
	interaction potentials},
  journal = {Physics of Plasmas},
  year = {1994},
  volume = {1},
  pages = {2515-2518},
  number = {8},
  doi = {10.1063/1.870578},
  keywords = {COULOMB SCATTERING; POTENTIAL ENERGY; SCREENING; KINETIC EQUATIONS;
	TRANSPORT THEORY; STOPPING POWER; ELECTRON COLLISIONS; ION COLLISIONS;
	ELECTRONION COLLISIONS; NUMERICAL SOLUTION; DEBYE LENGTH; PLASMA},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/1/2515/1}
}

@ARTICLE{ipython,
  author = {Fernando Perez and Brian E. Granger},
  title = {{IP}ython: A System for Interactive Scientific Computing},
  journal = {Computing in Science \& Engineering},
  year = {2007},
  volume = {9},
  pages = {90},
  owner = {mrterry},
  timestamp = {2010.06.10}
}

@MISC{perkins_personal,
  author = {Perkins, L. J.},
  howpublished = {personal communication},
  year = {2010},
  owner = {mrterry},
  timestamp = {2010.06.25}
}

@ARTICLE{Perkins2009,
  author = {Perkins, L. J. and Betti, R. and LaFortune, K. N. and Williams, W.
	H.},
  title = {Shock Ignition: A New Approach to High Gain Inertial Confinement
	Fusion on the National Ignition Facility},
  journal = {Phys. Rev. Lett.},
  year = {2009},
  volume = {103},
  pages = {045004},
  number = {4},
  month = {Jul},
  doi = {10.1103/PhysRevLett.103.045004},
  numpages = {4},
  publisher = {American Physical Society}
}

@ARTICLE{perkins81,
  author = {Sterrett T. Perkins and Dermott E. Cullen},
  title = {Elastic Nuclear Plus Interference Cross Sections for Light-Charged
	Particles},
  journal = {Nuclear Science and Engineering},
  year = {1981},
  volume = {77},
  pages = {20-39}
}

@TECHREPORT{perkins80,
  author = {Sterrett T. Perkins and Dermott E. Cullen},
  title = {Experimental and Evaluated Elastic Nuclear Plus Interference Cross
	Sections for Light Charged Particles},
  institution = {Lawrence Livermore National Laboratory},
  year = {1980},
  file = {perkins80.pdf:perkins80.pdf:PDF},
  otherinfo = {UCRL-50400, Vol. 15, Part F}
}

@ARTICLE{peter91,
  author = {Peter, Thomas and Meyer-ter-Vehn, J\"urgen },
  title = {Energy loss of heavy ions in dense plasma. I. Linear and nonlinear
	Vlasov theory for the stopping power},
  journal = {Phys. Rev. A},
  year = {1991},
  volume = {43},
  pages = {1998--2014},
  number = {4},
  month = {Feb},
  doi = {10.1103/PhysRevA.43.1998},
  file = {peter91.pdf:peter91.pdf:PDF},
  numpages = {16}
}

@ARTICLE{f2py,
  author = {Pearu Peterson},
  title = {F2PY: a tool for connecting Fortran and Python programs},
  journal = {International Journal of Computational Science and Engineering},
  year = {2009},
  volume = {4},
  pages = {296-305},
  owner = {mrterry},
  timestamp = {2010.06.10}
}

@ARTICLE{Peterson2002,
  author = {Robert R. Peterson and Donald A. Haynes, Jr. and Igor E. Golovkin
	and Gregory A. Moses},
  title = {Inertial fusion energy target output and chamber response: Calculations
	and experiments},
  journal = {Review,Tutorial and Invited Papers from the 43rd Annual Meeting of
	the APS Division of Plasma Physics},
  year = {2002},
  volume = {9},
  pages = {2287-2292},
  number = {5},
  doi = {10.1063/1.1464543},
  keywords = {plasma inertial confinement; fusion reactor targets; fusion reactor
	reaction chamber; X-ray effects; ion beam effects; nuclear engineering
	computing},
  location = {Long Beach, California (USA)},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/9/2287/1}
}

@ARTICLE{Halen1986,
  author = {PHalen, P. Van and Pulfrey, D. L.},
  title = {Erratum: "Accurate, short series approximation to Fermi--Dirac integrals
	of order -1/2, 1/2, 1, 3/2, 2, 5/2, 3, and 7/2''},
  journal = {Journal of Applied Physics},
  year = {1986},
  volume = {59},
  pages = {2264-2265},
  number = {6},
  doi = {10.1063/1.337053},
  file = {Halen1986.pdf:Halen1986.pdf:PDF},
  owner = {mrterry},
  publisher = {AIP},
  timestamp = {2008.01.24},
  url = {http://link.aip.org/link/?JAP/59/2264/1}
}

@BOOK{quadpack,
  title = {{Quadpack. A subroutine package for automatic integration}},
  publisher = {Springer},
  year = {1983},
  editor = {{Piessens, R., de Doncker-Kapenga, E., \& Ueberhuber, C.~W.}},
  author = {{Piessens}, R. and {de Doncker-Kapenga}, E. and {Ueberhuber}, C.~W.
	},
  adsnote = {Provided by the SAO/NASA Astrophysics Data System},
  adsurl = {http://adsabs.harvard.edu/abs/1983qspa.book.....P},
  booktitle = {Springer Series in Computational Mathematics, Berlin: Springer, 1983}
}

@ARTICLE{Piriz1996,
  author = {A.R. Piriz},
  title = {Conditions for the ignition of imploding spherical shell targets},
  journal = {Nuclear Fusion},
  year = {1996},
  volume = {36},
  pages = {1395},
  number = {10},
  abstract = {An analytical model for the study of the conditions for central ignition
	of imploding shell targets is presented. The model is based on a
	description of the stagnation phase in which the shell is considered
	to stagnate isentropically except in a central region of the fuel
	where the ignition profiles are determined by the competition of
	the energy losses due to thermal conduction and radiation with the
	heating due to compressional work and alpha particle deposition of
	energy. As a result, the temperature and the confinement parameter
	of the central spark are found to be dependent on the implosion velocity
	upsilon 0 , and the ignition conditions are obtained consistently
	with the implosion dynamics. In addition, the minimum energy of the
	beam E B ign required for ignition is calculated and the scaling
	E B ign varies as upsilon 0 -5 is found, which is in good agreement
	with previously reported simulations},
  file = {:Piriz1996.pdf:PDF},
  url = {http://stacks.iop.org/0029-5515/36/i=10/a=I13}
}

@ARTICLE{Piriz1994,
  author = {A R Piriz and S Atzeni},
  title = {Spherically symmetric radiation converters for ion beam fusion},
  journal = {Plasma Physics and Controlled Fusion},
  year = {1994},
  volume = {36},
  pages = {451},
  number = {3},
  abstract = {Thick spherical shells, irradiated nearly symmetrically by ion beams,
	can convert efficiently ion beam energy to thermal radiation, with
	parameters of relevance to inertial confinement fusion. The evolution
	of such radiation converters has been studied by means of an analytic
	model, in turn validated by 1D radiation hydrodynamic simulations.
	Expressions are derived for the overall conversion efficiency, the
	heating time and the radiation temperature as a function of the beam
	and target parameters. Conditions are also derived for the effective
	hydrodynamic insulation between the converter and the fusion capsule
	contained inside the converter. For realistic heavy ion beam parameters
	(e.g. 6-8 GeV Bi beams, with total energy of 10 MJ and power about
	700 TW) such converters can achieve an efficiency adequate for fusion
	applications, but only allow for a modest dynamic range of pulse
	shaping.},
  file = {:Piriz1994.pdf:PDF},
  url = {http://stacks.iop.org/0741-3335/36/i=3/a=006}
}

@ARTICLE{Prechelt2000,
  author = {Prechelt, L.},
  title = {An empirical comparison of seven programming languages},
  journal = {Computer},
  year = {2000},
  volume = {33},
  pages = {23 -29},
  number = {10},
  month = {oct},
  abstract = {Often heated, debates regarding different programming languages' effectiveness
	remain inconclusive because of scarce data and a lack of direct comparisons.
	The author addresses that challenge, comparatively analyzing 80 implementations
	of the phone-code program in seven different languages (C, C++, Java,
	Perl, Python, Rexx and Tcl). Further, for each language, the author
	analyzes several separate implementations by different programmers.
	The comparison investigates several aspects of each language, including
	program length, programming effort, runtime efficiency, memory consumption,
	and reliability. The author uses comparisons to present insight into
	program language performance},
  doi = {10.1109/2.876288},
  issn = {0018-9162},
  keywords = {C language;C++;Java;Perl;Python;Rexx;Tcl;memory consumption;phone-code
	program;program language performance;program length;programming language
	comparison;runtime efficiency;software reliability;C language;C++
	language;Java;Perl;authoring languages;programming;}
}

@ARTICLE{Prigogine1960,
  author = {I. Prigogine and Balescu, R.},
  title = {Irreversible Processes in Gases III: Inhomogeneous Systems},
  journal = {Physica},
  year = {1960},
  volume = {26},
  pages = {145-159},
  file = {Prigogine1960.pdf:Prigogine1960.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.04.03}
}

@ARTICLE{Prigogine1959,
  author = {Prigogine, I. and Balescu, R.},
  title = {Irreversible Processes in Gases II: The Equations of Evolution},
  journal = {Physica},
  year = {1959},
  volume = {25},
  pages = {302-323},
  file = {Prigogine1959.pdf:Prigogine1959.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.04.03}
}

@ARTICLE{Prigogine1959a,
  author = {Prigogine, I. and Balescu, R.},
  title = {Irreversible Processes in Gases I: The Diagram Technique},
  journal = {Physica},
  year = {1959},
  volume = {25},
  pages = {281-301},
  file = {Prigogine1959a.pdf:Prigogine1959a.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.04.03}
}

@ARTICLE{bucky,
  author = {R.R. Peterson, J.J. MacFarlane, G.A. Mose},
  title = {BUCKY?A 1-D Radiation Hydrodynamics Code for Simulating Inertial
	Confinement Fusion High Energy Density Plasmas},
  journal = {Univerisity of Wisconsin Fusion Design Memo},
  year = {1995},
  volume = {984},
  owner = {mrterry},
  timestamp = {2009.05.02}
}

@ARTICLE{Radha2005,
  author = {P. B. Radha and V. N. Goncharov and T. J. B. Collins and J. A. Delettrez
	and Y. Elbaz and V. Yu. Glebov and R. L. Keck and D. E. Keller and
	J. P. Knauer and J. A. Marozas and F. J. Marshall and P. W. McKenty
	and D. D. Meyerhofer and S. P. Regan and T. C. Sangster and D. Shvarts
	and S. Skupsky and Y. Srebro and R. P. J. Town and C. Stoeckl},
  title = {Two-dimensional simulations of plastic-shell, direct-drive implosions
	on OMEGA},
  journal = {Physics of Plasmas},
  year = {2005},
  volume = {12},
  pages = {032702n},
  number = {3},
  eid = {032702},
  comment = {DRACO paper},
  doi = {10.1063/1.1857530},
  file = {Radha-2005.pdf:Radha-2005.pdf:PDF},
  keywords = {plasma simulation; explosions; plasma heating by laser; plasma flow;
	plasma accelerators; surface roughness; laser ablation; Rayleigh-Taylor
	instability},
  numpages = {18},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/12/032702/1}
}

@ARTICLE{Ribeyre2009,
  author = {X Ribeyre and G Schurtz and M Lafon and S Galera and S Weber},
  title = {Shock ignition: an alternative scheme for HiPER},
  journal = {Plasma Physics and Controlled Fusion},
  year = {2009},
  volume = {51},
  pages = {015013},
  number = {1},
  abstract = {Two main paths are now under investigation that aim at thermonuclear
	ignition of hydrogen isotopes using lasers: central hot spot self-ignition
	and externally driven fast ignition of preassembled fuel. A third,
	intermediate, scheme is shock ignition, which combines the simplicity
	of self-ignition capsules to the hydrodynamic robustness of the fast
	ignition fuel assembly. This study addresses the potential of shock
	ignition for the HiPER project and provides a preliminary assessment
	of possible detrimental effects. Monodimensional simulations are
	performed to study the robustness of the ignition scheme in terms
	of shock launching time and laser power. Bidimensional simulations
	address the sensitivity of shock ignition to irradiation nonuniformity
	and to low mode asymmetries of the fuel assembly.},
  url = {http://stacks.iop.org/0741-3335/51/i=1/a=015013}
}

@ARTICLE{Ritchie1959,
  author = {Ritchie, R. H.},
  title = {Interaction of Charged Particles with a Degenerate Fermi-Dirac Electron
	Gas},
  journal = {Phys. Rev.},
  year = {1959},
  volume = {114},
  pages = {644--654},
  number = {3},
  month = {May},
  doi = {10.1103/PhysRev.114.644},
  file = {Ritchie1959.pdf:Ritchie1959.pdf:PDF},
  numpages = {10},
  owner = {mterry},
  timestamp = {2007.10.30}
}

@ARTICLE{rosenbluth57,
  author = {Rosenbluth, Marshall N. and MacDonald, William M. and Judd, David
	L.},
  title = {{F}okker-{P}lanck Equation for an Inverse-Square Force},
  journal = {Phys. Rev.},
  year = {1957},
  volume = {107},
  pages = {1--6},
  number = {1},
  month = {Jul},
  doi = {10.1103/PhysRev.107.1},
  file = {rosenbluth57.pdf:rosenbluth57.pdf:PDF},
  numpages = {5},
  publisher = {American Physical Society}
}

@ARTICLE{Rosner2000,
  author = {Rosner, R. and Calder, A.~C. and Dursi, L.~J. and Fryxell, B. and
	Lamb, D.~Q. and Niemeyer, J.~C. and Olson, K. and Ricker, P. and
	Timmes, F.~X. and Truran, J.~W. and Tufo, H. and Young, Y. and Zingale,
	M. and Lusk, E. and Stevens, R.},
  title = {Flash Code: Studying Astrophysical Thermonuclear Flashes},
  journal = {Computing in Science and Engineering, vol.~2, p.~33.},
  year = {2000},
  volume = {2},
  pages = {33-+}
}

@ARTICLE{Rostoker1960,
  author = {Norman Rostoker and M. N. Rosenbluth},
  title = {Test Particles in a Completely Ionized Plasma},
  journal = {Physics of Fluids},
  year = {1960},
  volume = {3},
  pages = {1-14},
  number = {1},
  doi = {10.1063/1.1705998},
  file = {Rostoker1960.pdf:Rostoker1960.pdf:PDF},
  owner = {matt},
  publisher = {AIP},
  timestamp = {2008.03.21},
  url = {http://link.aip.org/link/?PFL/3/1/1}
}

@ARTICLE{Ruzic1993,
  author = {D. N. Ruzic},
  title = {The effects of elastic scattering in neutral atom transport},
  journal = {Physics of Fluids B: Plasma Physics},
  year = {1993},
  volume = {5},
  pages = {3140-3147},
  number = {9},
  doi = {10.1063/1.860651},
  keywords = {ELASTIC SCATTERING; NEUTRAL PARTICLES; HYDROGEN; HYDROGEN IONS; HELIUM;
	IMPACT PARAMETER; INTERATOMIC FORCES; POTENTIALS; WAVE FUNCTIONS;
	TRANSPORT; DIVERTORS; ATOM COLLISIONS},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PFB/5/3140/1}
}

@ARTICLE{ryutov92,
  author = {Dmitri Ryutov},
  title = {Energetic Ion Population Formed in Close Collision with Fusion Alpha-Particles},
  journal = {Physica Scripta},
  year = {1992},
  volume = {45},
  pages = {153-158},
  doi = {10.1088/0031-8949/45/2/014},
  file = {ryutov92.pdf:ryutov92.pdf:PDF}
}

@ARTICLE{Sacks1982,
  author = {R.A. Sacks and R.C. Arnold and G.R. Magelssent},
  title = {Irradiation uniformity of spherical heavy-ion-driven ICF targets},
  journal = {Nuclear Fusion},
  year = {1982},
  volume = {22},
  pages = {1421},
  number = {11},
  abstract = {Estimates are presented for non-uniformity of energy deposition in
	spherical-shell ICF targets driven by beams of high-energy heavy
	ions. The principal consideration is shown to be the difference in
	penetration depth of ions entering at different angles relative to
	the surface of the sphere. Calculations are reported for 12-, 20-,
	and 32-beam symmetrical illumination. A rough assessment of required
	implosion symmetry indicates that a trade-off will exist between
	target gain and number of beams. A brief discussion of possible angular
	pressure-smoothing mechanisms is included.},
  url = {http://stacks.iop.org/0029-5515/22/i=11/a=002}
}

@ARTICLE{Salpeter1954,
  author = {E. E. Salpeter},
  title = {Electron Screeing and Thermonuclear Reactions},
  journal = {Australian Journal of Physics},
  year = {1954},
  volume = {7},
  pages = {373-388},
  file = {Salpeter1954.pdf:Salpeter1954.pdf:PDF},
  owner = {mterry},
  timestamp = {2007.10.30}
}

@ARTICLE{Sangster2010,
  author = {T. C. Sangster and V. N. Goncharov and R. Betti and T. R. Boehly
	and D. T. Casey and T. J. B. Collins and R. S. Craxton and J. A.
	Delettrez and D. H. Edgell and R. Epstein and K. A. Fletcher and
	J. A. Frenje and Y. Yu. Glebov and D. R. Harding and S. X. Hu and
	I. V. Igumenschev and J. P. Knauer and S. J. Loucks and C. K. Li
	and J. A. Marozas and F. J. Marshall and R. L. McCrory and P. W.
	McKenty and D. D. Meyerhofer and P. M. Nilson and S. P. Padalino
	and R. D. Petrasso and P. B. Radha and S. P. Regan and F. H. Seguin
	and W. Seka and R. W. Short and D. Shvarts and S. Skupsky and V.
	A. Smalyuk and J. M. Soures and C. Stoeckl and W. Theobald and B.
	Yaakobi},
  title = {Shock-tuned cryogenic-deuterium-tritium implosion performance on
	Omega},
  journal = {Physics of Plasmas},
  year = {2010},
  volume = {17},
  pages = {056312},
  number = {5},
  eid = {056312},
  doi = {10.1063/1.3360928},
  file = {:Sangster2010.pdf:PDF},
  keywords = {cryogenics; deuterium; explosions; plasma diagnostics; plasma heating;
	plasma inertial confinement; plasma shock waves; plasma temperature;
	tritium},
  numpages = {7},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/17/056312/1}
}

@ARTICLE{Sanz1992,
  author = {J. Sanz and A. R. Piriz and F. G. Tomasel},
  title = {Self-similar model for tamped ablation driven by thermal radiation},
  journal = {Physics of Fluids B: Plasma Physics},
  year = {1992},
  volume = {4},
  pages = {683-692},
  number = {3},
  doi = {10.1063/1.860266},
  file = {Sanz1992.pdf:Sanz1992.pdf:PDF},
  keywords = {ABLATION; THERMAL RADIATION; SELFSIMILIAR STATES; ION BEAM TARGETS;
	BLACKBODY RADIATION; SCALING LAWS; ABSORBERS; RADIATION TRANSPORT;
	INERTIAL CONFINEMENT; CONVECTION; FLOW MODELS; PLASMA PRODUCTION},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PFB/4/683/1}
}

@ARTICLE{Schmitt2010,
  author = {Andrew J. Schmitt and Jason W. Bates and Steven P. Obenschain and
	Steven T. Zalesak and David E. Fyfe},
  title = {Shock ignition target design for inertial fusion energy},
  journal = {Physics of Plasmas},
  year = {2010},
  volume = {17},
  pages = {042701},
  number = {4},
  eid = {042701},
  doi = {10.1063/1.3385443},
  keywords = {explosions; plasma inertial confinement; plasma shock waves; plasma
	simulation; Rayleigh-Taylor instability},
  numpages = {14},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/17/042701/1}
}

@MISC{Schurtz,
  author = {Schurtz, G},
  howpublished = {private communiation},
  owner = {terry10},
  timestamp = {2012.04.11}
}

@ARTICLE{Seele1998,
  author = {Seele, Cord and Zwicknagel, G\"unter and Toepffer, Christian and
	Reinhard, Paul-Gerhard },
  title = {Time-dependent stopping power and influence of an infinite magnetic
	field},
  journal = {Phys. Rev. E},
  year = {1998},
  volume = {57},
  pages = {3368--3378},
  number = {3},
  month = {Mar},
  doi = {10.1103/PhysRevE.57.3368},
  file = {Seele1998.pdf:Seele1998.pdf:PDF},
  numpages = {10},
  owner = {mterry},
  timestamp = {2007.10.29}
}

@ARTICLE{seguin02,
  author = {F. H. Seguin and C. K. Li and J. A. Frenje},
  title = {Using secondary-proton spectra to study the compression and symmetry
	of deuterium-filled capsules at OMEGA},
  journal = {Physics of Plasmas},
  year = {2002},
  volume = {9},
  pages = {2725-2737},
  doi = {10.1063/1.1472502},
  file = {seguin02.pdf:seguin02.pdf:PDF}
}

@ARTICLE{siambis76,
  author = {Siambis, John G.},
  title = {Resonances in Binary Charged-Particle Collisions in a Uniform Magnetic
	Field},
  journal = {Phys. Rev. Lett.},
  year = {1976},
  volume = {37},
  pages = {1750--1753},
  number = {26},
  month = {Dec},
  doi = {10.1103/PhysRevLett.37.1750},
  file = {siambis76.pdf:siambis76.pdf:PDF},
  numpages = {3},
  owner = {mterry},
  publisher = {American Physical Society},
  timestamp = {2007.10.29}
}

@ARTICLE{Simon1983,
  author = {A. Simon and R. W. Short and E. A. Williams and T. Dewandre},
  title = {On the inhomogeneous two-plasmon instability},
  journal = {Physics of Fluids},
  year = {1983},
  volume = {26},
  pages = {3107-3118},
  number = {10},
  doi = {10.1063/1.864037},
  keywords = {inhomogeneous plasma; hot plasma; plasmons; wave propagation; electromagnetic
	radiation; plasma instability; parametric instabilities; eigenvalues;
	schroedinger equation; wkb approximation; perturbation theory; analytical
	solution; computer codes; threshold energy; instability growth rates},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PFL/26/3107/1}
}

@ARTICLE{skupsky77,
  author = {Skupsky, Stanley },
  title = {Energy loss of ions moving through high-density matter},
  journal = {Phys. Rev. A},
  year = {1977},
  volume = {16},
  pages = {727--731},
  number = {2},
  month = {Aug},
  doi = {10.1103/PhysRevA.16.727},
  file = {skupsky77.pdf:skupsky77.pdf:PDF},
  numpages = {4}
}

@ARTICLE{Skupsky2004,
  author = {S. Skupsky and J. A. Marozas and R. S. Craxton and R. Betti and T.
	J. B. Collins and J. A. Delettrez and V. N. Goncharov and P. W. McKenty
	and P. B. Radha and T. R. Boehly and J. P. Knauer and F. J. Marshall
	and D. R. Harding and J. D. Kilkenny and D. D. Meyerhofer and T.
	C. Sangster and R. L. McCrory},
  title = {Polar direct drive on the National Ignition Facility},
  journal = {45th Annual Meeting of the APS Division of Plasma Physics},
  year = {2004},
  volume = {11},
  pages = {2763-2770},
  number = {5},
  doi = {10.1063/1.1689665},
  keywords = {explosions; plasma simulation; laser fusion; fusion reactor ignition;
	fusion reactor targets; plasma instability},
  location = {Albuquerque, New Mexico (USA)},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/11/2763/1}
}

@ARTICLE{Someya2004,
  author = {Someya, Tetsuo and Ogoyski, Aleksandar I. and Kawata, Shigeo and
	Sasaki, Toru },
  title = {Heavy-ion beam illumination on a direct-driven pellet in heavy-ion
	inertial fusion},
  journal = {Phys. Rev. ST Accel. Beams},
  year = {2004},
  volume = {7},
  pages = {044701},
  number = {4},
  month = {Apr},
  doi = {10.1103/PhysRevSTAB.7.044701},
  file = {:Someya2004.pdf:PDF},
  numpages = {13},
  publisher = {American Physical Society}
}

@BOOK{Spitzer1956,
  title = {Physics of Fully Ionized Gases},
  publisher = {Interscience Publishers, Inc.},
  year = {1956},
  author = {Spitzer, Lyman Spitzer, Jr.},
  owner = {mrterry},
  timestamp = {2008.02.28}
}

@ELECTRONIC{pexpect,
  author = {Noah Spurrier},
  year = {2010},
  title = {Pexpect version 2.3},
  url = {http://www.noah.org/wiki/Pexpect},
  owner = {mrterry},
  timestamp = {2010.07.19}
}

@ARTICLE{Steinberg2001,
  author = {Steinberg, M. and Ortner, J. },
  title = {Energy loss of a charged particle in a magnetized quantum plasma},
  journal = {Phys. Rev. E},
  year = {2001},
  volume = {63},
  pages = {046401},
  number = {4},
  month = {Mar},
  doi = {10.1103/PhysRevE.63.046401},
  file = {Steinberg2001.pdf:Steinberg2001.pdf:PDF},
  numpages = {10},
  owner = {mterry},
  timestamp = {2007.10.29}
}

@ARTICLE{Tabak2001,
  author = {Max Tabak},
  title = {New Targets for Intertial Fusion},
  journal = {Science and Technology Review},
  year = {2001},
  volume = {November},
  owner = {mrterry},
  timestamp = {2010.07.23},
  url = {https://www.llnl.gov/str/November01/Tabak.html}
}

@ARTICLE{Tabak1998,
  author = {Max Tabak and Debra Callahan-Miller},
  title = {Design of a distributed radiator target for inertial fusion driven
	from two sides with heavy ion beams},
  journal = {Nuclear Instruments and Methods in Physics Research Section A: Accelerators,
	Spectrometers, Detectors and Associated Equipment},
  year = {1998},
  volume = {415},
  pages = {75 - 84},
  number = {1-2},
  abstract = {We describe the status of a distributed radiator heavy ion target
	design. In integrated calculations this target ignited and produced
	390-430?MJ of yield when driven with 5.8-6.5?MJ of 3-4?GeV Pb ions.
	The target has cylindrical symmetry with disk endplates. The ions
	uniformly illuminate these endplates in a 5?mm radius spot. We discuss
	the considerations which led to this design together with some previously
	unused design features: low-density hohlraum walls in approximate
	pressure balance with internal low-Z fill materials, radiation symmetry
	determined by the position of the radiator materials and particle
	ranges, and early time pressure symmetry possibly influenced by radiation
	shims. We discuss how this target scales to lower input energy or
	to lower beam power. Variant designs with more realistic beam focusing
	strategies are also discussed. We show the tradeoffs required for
	targets which accept higher particle energies. Finally, the impact
	of the fast ignitor concept on heavy ion fusion is discussed.},
  doi = {DOI: 10.1016/S0168-9002(98)00371-4},
  file = {:Tabak1998.pdf:PDF},
  issn = {0168-9002},
  url = {http://www.sciencedirect.com/science/article/B6TJM-3WTWW5M-B/2/56b5690daf99588556cdc563fb30c028}
}

@ARTICLE{Tahir1989,
  author = {N. A. Tahir and R. C. Arnold},
  title = {Radiation transport effects in heavy-ion beam--target interaction
	studies: Measurement of target opacity and beam conversion efficiency},
  journal = {Physics of Fluids B: Plasma Physics},
  year = {1989},
  volume = {1},
  pages = {1526-1538},
  number = {7},
  doi = {10.1063/1.858929},
  keywords = {SIMULATION; TARGETS; CYLINDERS; ION BEAMS; HEAVY IONS; SYNCHROTRONS;
	THERMONUCLEAR REACTIONS; CONVERSION; EFFICIENCY; BEAMPLASMA SYSTEMS;
	THERMAL RADIATION},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PFB/1/1526/1}
}

@ARTICLE{Tahir2000,
  author = {Tahir, N. A. and Hoffmann, D. H. H. and Kozyreva, A. and Shutov,
	A. and Maruhn, J. A. and Neuner, U. and Tauschwitz, A. and Spiller,
	P. and Bock, R. },
  title = {Shock compression of condensed matter using intense beams of energetic
	heavy ions},
  journal = {Phys. Rev. E},
  year = {2000},
  volume = {61},
  pages = {1975--1980},
  number = {2},
  month = {Feb},
  doi = {10.1103/PhysRevE.61.1975},
  file = {:Tahir2000.pdf:PDF},
  numpages = {5},
  publisher = {American Physical Society}
}

@ARTICLE{Tahir1992,
  author = {N. A. Tahir and D. H. H. Hoffmann and J. A. Maruhn and T. Blenski
	and J. Ligou and C. Deutsch},
  title = {Simulations of compression and thermonuclear burn of an indirect
	drive reactor-size inertial fusion target},
  journal = {Physics Letters A},
  year = {1992},
  volume = {172},
  pages = {162 - 168},
  number = {3},
  abstract = {In this paper we present one-dimensional numerical simulations of
	compression and burn of a high-gain indirect drive inertial fusion
	target suitable for use in a reactor system. The target consists
	of a capsule that contains 4.45 mg of DT fuel and the capsule is
	enclosed in a solid gold casing. The inner radius of the casing is
	twice larger than the outer radius of the capsule so that the inner
	surface area of the hohlraum wall is four times larger than the capsule
	surface area. The cavity is filled with a homogeneous radiation field
	whose intensity increases in time in an appropriate manner reaching
	a maximum radiation temperature of 300 eV. The capsule is driven
	to thermonuclear burn by this radiation field. The target (capsule+casing)
	absorbs an input energy of about 5.6 MJ and the implosion produces
	an output energy of 720 MJ so that the overall energy gain of this
	target is of the order of 130.},
  doi = {DOI: 10.1016/0375-9601(92)90976-S},
  file = {:Tahir1992.pdf:PDF},
  issn = {0375-9601},
  url = {http://www.sciencedirect.com/science/article/B6TVM-46SXM98-VF/2/ecd94fa37a628e60b531a4063ae388ed}
}

@ARTICLE{Tahir1995,
  author = {N A Tahir and D H H Hoffmann and J A Maruhn and C Deutsch},
  title = {Analysis of compression, thermonuclear burn and hydrodynamic stability
	of a reactor-size radiation driven inertial fusion target},
  journal = {Plasma Physics and Controlled Fusion},
  year = {1995},
  volume = {37},
  pages = {447},
  number = {4},
  abstract = {This paper presents one-dimensional numerical simulations of implosion
	of a reactor-size, indirect drive inertial confinement fusion target
	that consists of a capsule surrounded by a solid gold casing. The
	radius of the casing is twice the outer radius of the capsule so
	that the casing to capsule surface area ratio is 4. The capsule absorbs
	about 3 MJ input radiation energy while 2.4 MJ energy is lost into
	the casing wall. The implosion yields an output thermonuclear energy
	of 770 MJ so that the capsule gain, G c , is about 257 while the
	target gain G t , is of the order of 140. It has been found that
	the hydrodynamic stability of the target during the compression phase
	is substantially improved due to ablative effects. Moreover, a parameter
	study of the target gain versus input pulse parameters shows that
	the target gain may be insensitive to changes in the input parameters
	over a wide range.},
  file = {:Tahir1995.pdf:PDF},
  url = {http://stacks.iop.org/0741-3335/37/i=4/a=006}
}

@ARTICLE{Tahir1999,
  author = {Tahir, N. A. and Hoffmann, D. H. H. and Maruhn, J. A. and Spiller,
	P. and Bock, R. },
  title = {Heavy-ion-beam--induced hydrodynamic effects in solid targets},
  journal = {Phys. Rev. E},
  year = {1999},
  volume = {60},
  pages = {4715--4724},
  number = {4},
  month = {Oct},
  doi = {10.1103/PhysRevE.60.4715},
  file = {:Tahir1999.pdf:PDF},
  numpages = {9},
  publisher = {American Physical Society}
}

@ARTICLE{Tahir2001,
  author = {N. A. Tahir and A. Kozyreva and P. Spiller and D. H. H. Hoffman and
	A. Shutov},
  title = {Influence of hydrodynamic expansion on specific power deposition
	by a heavy ion beam in matter},
  journal = {Physics of Plasmas},
  year = {2001},
  volume = {8},
  pages = {611-615},
  number = {2},
  doi = {10.1063/1.1339229},
  file = {:Tahir2001.pdf:PDF},
  keywords = {ion beams; digital simulation; hydrodynamics; energy loss of particles},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/8/611/1}
}

@ARTICLE{Theobald2008,
  author = {W. Theobald and R. Betti and C. Stoeckl and K. S. Anderson and J.
	A. Delettrez and V. Yu. Glebov and V. N. Goncharov and F. J. Marshall
	and D. N. Maywar and R. L. McCrory and D. D. Meyerhofer and P. B.
	Radha and T. C. Sangster and W. Seka and D. Shvarts and V. A. Smalyuk
	and A. A. Solodov and B. Yaakobi and C. D. Zhou and J. A. Frenje
	and C. K. Li and F. H. Seguin and R. D. Petrasso and L. J. Perkins},
  title = {Initial experiments on the shock-ignition inertial confinement fusion
	concept},
  journal = {Physics of Plasmas},
  year = {2008},
  volume = {15},
  pages = {056306},
  number = {5},
  eid = {056306},
  doi = {10.1063/1.2885197},
  file = {Theobald2008.pdf:Theobald2008.pdf:PDF},
  keywords = {ignition; plasma inertial confinement; plasma production by laser;
	plasma shock waves; shock wave effects},
  numpages = {9},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/15/056306/1}
}

@ARTICLE{Toepffer2002,
  author = {Toepffer, Christian },
  title = {Scattering of magnetized electrons by ions},
  journal = {Phys. Rev. A},
  year = {2002},
  volume = {66},
  pages = {022714},
  number = {2},
  month = {Aug},
  doi = {10.1103/PhysRevA.66.022714},
  file = {Toepffer2002.pdf:Toepffer2002.pdf:PDF},
  numpages = {15},
  owner = {mterry},
  publisher = {American Physical Society},
  timestamp = {2007.10.29}
}

@INCOLLECTION{Trubnikov1965,
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  title = {Particle Interaction in a Fully Ionized Plasma},
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  publisher = {Consultants Bureau},
  year = {1965},
  editor = {M. A. Leontovich},
  volume = {1},
  pages = {105-204},
  file = {Trubnikov1965.pdf:Trubnikov1965.pdf:PDF},
  owner = {mrterry},
  timestamp = {2008.03.07}
}

@ARTICLE{Trubnikov1958,
  author = {Trubnikov, B. A.},
  journal = {J. Exptl. Theoret. Phys, USSR},
  year = {1958},
  volume = {34},
  pages = {1358},
  owner = {mrterry},
  timestamp = {2009.04.01}
}

@ARTICLE{slatec,
  author = {Vandevender,, W. H. and Haskell,, K. H.},
  title = {The SLATEC mathematical subroutine library},
  journal = {SIGNUM Newsl.},
  year = {1982},
  volume = {17},
  pages = {16--21},
  number = {3},
  address = {New York, NY, USA},
  doi = {http://doi.acm.org/10.1145/1057594.1057595},
  issn = {0163-5778},
  publisher = {ACM}
}

@BOOK{autotools,
  title = {{GNU} Autoconf, Automake and Libtool},
  publisher = {New Riders},
  year = {2000},
  author = {Gary V. Vaughan and Ben Elliston and Tom Tromey and Ian Lance Taylor},
  owner = {mrterry},
  timestamp = {2010.07.19},
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@ARTICLE{Velarde1986,
  author = {Velarde,G. and Aragones,J. M. and Gago,J. A. and Gamez,L. and Gonzalez,M.
	C. and Honrubia,J. J. and Hortal,J. L. and Martinez-Val,J. M. and
	Minguez,E. and OcaÒa,J. L. and Otero,R. and Perlado,J. M. and Santolaya,J.
	M. and Serrano,J. F. and Velarde,P. M.},
  title = {Analysis of directly driven ICF targets},
  journal = {Laser and Particle Beams},
  year = {1986},
  volume = {4},
  pages = {349-392},
  number = {3-4},
  abstract = { ABSTRACT In this article the current capabilities at DENIM for the
	analysis of directly driven targets are presented. These include
	theoretical, computational and applied physical studies and developments
	of detailed simulation models for the most relevant processes in
	ICF. The simulation of directly driven ICF targets is carried out
	with the one-dimensional NORCLA code developed at DENIM. This code
	contains two main segments: NORMA and CLARA, able to work fully coupled
	and in an iterative manner. NORMA solves the hydrodynamic equations
	in a lagrangian mesh. It has modular programs coupled to it to treat
	the laser or particle beam interaction with matter. Equations of
	state, opacities and conductivities are taken from a DENIM atomic
	data library, generated externally with other codes that will also
	be explained in this work. CLARA solves the transport equation for
	neutrons, (Boltzmann), as well as for charged particles, and suprathermal
	electrons (Fokker-Planck), using discrete ordinates and finite element
	methods in the computational procedure. Parametric calculations of
	multilayered single-shell targets driven by heavy ion beams are also
	analyzed. Finally, conclusions are focused on the ongoing developments
	in the areas of interest such as: radiation transport, atomic physics,
	particle in cell method, charged particle transport, two-dimensional
	calculations and instabilities. },
  doi = {10.1017/S0263034600002056},
  eprint = {http://journals.cambridge.org/article_S0263034600002056},
  url = {http://dx.doi.org/10.1017/S0263034600002056}
}

@ARTICLE{Velarde1989,
  author = {G. Velarde and J.M. AragonÈs and L. G·mez and C. Gonz·lez and J.J.
	Honrubia and J.M. MartÌnez-Val and E. MÌnguez and J.L. OcaÒa and
	J.M. Perlado and P.M. Velarde},
  title = {Recent results in the analysis of heavy-ion-beam-driven ICF targets},
  journal = {Nuclear Instruments and Methods in Physics Research Section A: Accelerators,
	Spectrometers, Detectors and Associated Equipment},
  year = {1989},
  volume = {278},
  pages = {105 - 109},
  number = {1},
  note = {Proceeding of the International Symposium on Heavy Ion Inertial Fusion
	Darmstadt, FRG, June 28-30, 1988},
  doi = {DOI: 10.1016/0168-9002(89)91142-X},
  issn = {0168-9002},
  url = {http://www.sciencedirect.com/science/article/B6TJM-472T50D-H2/2/37429cf52b37e85576d44f08d9f85a43}
}

@ARTICLE{Velarde1992,
  author = {Velarde, G. and Martinez-Val, J. M. and Gonz·lez, C. and Piera, M.
	and AragonÈs, J. and Gamez, L. and Honrubia, J. and Minguez, E. and
	Perlado, J. and Velarde, P. M.},
  title = {AN ANALYSIS OF THE IMPLOSION OF HEAVY ION
	
	DIRECTLY DRIVEN SIMPLE TARGETS},
  journal = {Particle Accelerators},
  year = {1992},
  volume = {37-38},
  pages = {527-542},
  file = {Velarde1992.pdf:Velarde1992.pdf:PDF},
  owner = {terry10},
  timestamp = {2011.04.28}
}

@MANUAL{IronPython,
  title = {IronPython},
  author = {Dino Viehland},
  organization = {MIcrosoft},
  month = {August},
  year = {2010},
  owner = {mrterry},
  timestamp = {2010.08.04},
  url = {http://ironpython.codeplex.com/}
}

@ARTICLE{Walter2000,
  author = {M. Walter and C. Toepffer and G. Zwicknagel},
  title = {Stopping power in anisotropic, magnetized electron plasmas},
  journal = {Nuclear Instruments and Methods in Physics Research B},
  year = {2000},
  volume = {168},
  pages = {347-361},
  doi = {10.1016/S0168-583X(99)01207-0},
  file = {Walter2000.pdf:Walter2000.pdf:PDF},
  owner = {mterry},
  timestamp = {2007.10.29}
}

@ARTICLE{wang98,
  author = {P. Wang and T. M. Mehlhorn and J. J. MacFarlane},
  title = {A unified self-consisten model for calculating ion stopping power
	in ICF plasma},
  journal = {Physics of Plasmas},
  year = {1998},
  volume = {5},
  pages = {2977-2987},
  doi = {10.1063/1.873022},
  file = {wang98.pdf:wang98.pdf:PDF}
}

@ARTICLE{Weinstock1964,
  author = {Weinstock, Jerome},
  title = {Theory of Irreversible Processes in a Plasma: Derivation of a Convergent
	Kinetic Equation from the Generalized Master Equation},
  journal = {Phys. Rev.},
  year = {1964},
  volume = {133},
  pages = {A673--A680},
  number = {3A},
  month = {Feb},
  doi = {10.1103/PhysRev.133.A673},
  file = {Weinstock1964.pdf:Weinstock1964.pdf:PDF},
  numpages = {7},
  owner = {mrterry},
  publisher = {American Physical Society},
  timestamp = {2008.04.14}
}

@ARTICLE{Weinstock1963,
  author = {Weinstock, Jerome},
  title = {Cluster Formulation of the Exact Equation for the Evolution of a
	Classical Many-Body System},
  journal = {Phys. Rev.},
  year = {1963},
  volume = {132},
  pages = {454--469},
  number = {1},
  month = {Oct},
  doi = {10.1103/PhysRev.132.454},
  file = {Weinstock1963.pdf:Weinstock1963.pdf:PDF},
  numpages = {15},
  owner = {mrterry},
  publisher = {American Physical Society},
  timestamp = {2008.04.03}
}

@BOOK{Wu1966,
  title = {Kinetic Equations of Gases and Plasmas},
  publisher = {Addison-Wesley Publishing Company},
  year = {1966},
  author = {Ta-You Wu},
  owner = {mrterry},
  timestamp = {2008.04.01}
}

@ARTICLE{yuan05,
  author = {J. Yuan and G. A. Moses and P. W. McKenty},
  title = {Monte {C}arlo charged-particle tracking and energy deposition on
	a Lagrangian mesh},
  journal = {Phys. Rev. E},
  year = {2005},
  volume = {72},
  pages = {046706},
  number = {4},
  eid = {046706},
  doi = {10.1103/PhysRevE.72.046706},
  file = {yuan05.pdf:yuan05.pdf:PDF},
  keywords = {plasma inertial confinement; Monte Carlo methods; mesh generation;
	plasma simulation},
  numpages = {11},
  publisher = {APS},
  url = {http://link.aps.org/abstract/PRE/v72/e046706}
}

@ARTICLE{Zhou2008,
  author = {C. D. Zhou and R. Betti},
  title = {A measurable Lawson criterion and hydro-equivalent curves for inertial
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  journal = {Physics of Plasmas},
  year = {2008},
  volume = {15},
  pages = {102707},
  number = {10},
  eid = {102707},
  doi = {10.1063/1.2998604},
  keywords = {hydrodynamics; ignition; plasma inertial confinement; plasma temperature},
  numpages = {12},
  publisher = {AIP},
  url = {http://link.aip.org/link/?PHP/15/102707/1}
}

@ARTICLE{Zwicknagel2000,
  author = {Günter Zwicknagel},
  title = {Nonlinear energy loss of highly charged heavy ions},
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  volume = {441},
  pages = {44-49},
  doi = {10.1016/S0168-9002(99)01106-7},
  file = {Zwicknagel2000.pdf:Zwicknagel2000.pdf:PDF},
  owner = {mterry},
  timestamp = {2007.10.29}
}

@BOOK{Brittin1967,
  title = {Lectures in Theoretical Physics Volume IX C: Kinetic Theory},
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  owner = {mrterry},
  timestamp = {2009.04.20}
}

@MANUAL{amsmathguide,
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  owner = {mrterry},
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@MANUAL{flash,
  title = {FLASH User's Guide},
  organization = {FLASH Center for Computational Science},
  owner = {terry10},
  timestamp = {2012.04.18},
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}

@ELECTRONIC{ipython-notebook,
  organization = {IPython},
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  timestamp = {2012.04.19}
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@MANUAL{PyPy,
  title = {PyPy},
  owner = {mrterry},
  timestamp = {2010.08.04},
  url = {http://codespeak.net/pypy/dist/pypy/doc/docindex.html}
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@MANUAL{StacklessPython,
  title = {Stackless Python},
  owner = {mrterry},
  timestamp = {2010.08.04},
  url = {http://www.disinterest.org/resource/stackless/2.6-docs-html/}
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@MANUAL{CPython,
  title = {Python/C API Reference Manual},
  organization = {Python Software Foundation},
  month = {August},
  year = {2010},
  owner = {mrterry},
  timestamp = {2010.08.04},
  url = {http://docs.python.org/c-api/}
}