1 “Berkeley Lab AMR”, project homepage, Lawrence Berkeley National Laboratory. URL (cited on 5 September 2003):
External Link
2 “ASC / Alliances Center for Astrophysical Thermonuclear Flashes”, project homepage, University of Chicago. URL (cited on 11 November 2009):
External Link
3 Agudo, I., Gómez, J.L., Martí, J.M., Ibáñez, J.M., Marscher, A.P., Alberdi, A., Aloy, M.A., and Hardee, P.E., “Jet stability and the generation of superluminal and stationary components”, Astrophys. J., 549, L183–L186, (2001). [External LinkDOI].
4 Akerlof, C., Balsano, R., Barthelmy, S., Bloch, J., Butterworth, P., Casperson, D., Cline, T., Fletcher, S., Frontera, F., Gisler, F., Heise, J., Hills, J., Kehoe, R., Lee, B., Marshall, S., McKay, T., Miller, R., Piro, L., Priedhorsky, W., Szymanski, J., and Wren, J., “Observation of contemporaneous optical radiation from a gamma-ray burst”, Nature, 398, 400–402, (1999). [External LinkDOI].
5 Aloy, M.A., Ibáñez, J.M., Martí, J.M., Gómez, J.L., and Müller, E., “High-resolution three-dimensional simulations of relativistic jets”, Astrophys. J. Lett., 523, L125–L128, (1999). [External LinkDOI].
6 Aloy, M.A., Ibáñez, J.M., Martí, J.M., and Müller, E., “GENESIS: A high-resolution code for three-dimensional relativistic hydrodynamics”, Astrophys. J. Suppl. Ser., 122, 151–166, (1999). [External LinkDOI].
7 Aloy, M.A., Müller, E., Ibáñez, J.M., Martí, J.M., and MacFadyen, A., “Relativistic Jets from Collapsars”, Astrophys. J. Lett., 531, L119–L122, (2000). [External LinkDOI].
8 Anile, A.M., Relativistic fluids and magneto-fluids: With applications in astrophysics and plasma physics, Cambridge Monographs on Mathematical Physics, (Cambridge University Press, Cambridge; New York, 1989). [External LinkGoogle Books].
9 Anile, A.M., and Pennisi, S., “On the mathematical structure of test relativistic magnetofluiddynamics”, Ann. Inst. Henri Poincare, 46, 27–44, (1987).
10 Anninos, P., and Fragile, P.C., “Nonoscillatory Central Difference and Artificial Viscosity Schemes for Relativistic Hydrodynamics”, Astrophys. J. Suppl. Ser., 144, 243–257, (2003). [External LinkDOI], [External Linkastro-ph/0206265].
11 Arnowitt, R., Deser, S., and Misner, C.W., “The dynamics of general relativity”, in Witten, L., ed., Gravitation: An Introduction to Current Research, pp. 227–265, (Wiley, New York; London, 1962). [External LinkDOI], [External LinkADS], [External Linkgr-qc/0405109].
12 Ayal, S., Piran, T., Oechslin, R., Davies, M.B., and Rosswog, S., “Post-Newtonian Smoothed Particle Hydrodynamics”, Astrophys. J., 550, 846–859, (2001). [External LinkDOI].
13 Balsara, D.S., “Riemann Solver for Relativistic Hydrodynamics”, J. Comput. Phys., 114, 284–297, (1994). [External LinkDOI].
14 Balsara, D.S., “Total Variation Diminishing Scheme for Relativistic Magnetohydrodynamics”, Astrophys. J. Suppl. Ser., 132, 83–101, (2001). [External LinkDOI].
15 Banyuls, F., Font, J.A., Ibáñez, J.M., Marti, J.M., and Miralles, J.A., “Numerical 3+1 General Relativistic Hydrodynamics: a Local Characteristic Approach”, Astrophys. J., 476, 221–231, (1997). [External LinkDOI].
16 Bate, M.R., and Burkert, A., “Resolution requirements for smoothed particle hydrodynamics calculations with self-gravity”, Mon. Not. R. Astron. Soc., 288, 1060–1072, (1997).
17 Begelman, M.C., Blandford, R.D., and Rees, M.J., “Theory of Extragalactic Radio Sources”, Rev. Mod. Phys., 56, 255–351, (1984).
18 Bell, J.B., Colella, P., and Glaz, H.M., “A second-order projection method for the incompressible Navier–Stokes equations”, J. Comput. Phys., 85, 257–283, (1989). [External LinkDOI].
19 Ben-Artzi, M., “The generalized Riemann problem for reactive flows”, J. Comput. Phys., 81, 70–101, (1989). [External LinkDOI].
20 Benz, W., “Smooth Particle Hydrodynamics: A Review”, in Buchler, J.R., ed., The Numerical Modelling of Nonlinear Stellar Pulsations, Problems and Prospects, Proceedings of the NATO Advanced Research Workshop, Les Arcs, France, March 20 – 24, 1989, NATO Science Series, vol. 302, pp. 269–293, (Kluwer, Dordrecht, 1990).
21 Berger, M.J., and Colella, P., “Local Adaptive Mesh Refinement for Shock Hydrodynamics”, J. Comput. Phys., 82, 64–84, (1989). [External LinkDOI].
22 Bicknell, G.V., “Decelerating Relativistic Jets and the Fanaroff-Riley Classification”, in Hardee, P.E., Bridle, A.H., and Zensus, J.A, eds., Energy Transport in Radio Galaxies and Quasars, Proceedings of a workshop held in Tuscaloosa, Alabama, 19 – 23 September 1995, ASP Conference Series, vol. 100, pp. 253–260, (Astronomical Society of the Pacific, San Francisco, 1996).
23 Birkinshaw, M., “The Stability of Jets”, in Hughes, P.A., ed., Beams and Jets in Astrophysics, Cambridge Astrophysics Series, vol. 19, pp. 278–341, (Cambridge University Press, Cambridge; New York, 1991). [External LinkGoogle Books].
24 Bishop, N.T., Gómez, R., Lehner, L., Maharaj, M., and Winicour, J., “High-powered gravitational news”, Phys. Rev. D, 56, 6298–6309, (1997). [External LinkDOI], [External LinkADS].
25 Blandford, R.D., and Königl, A., “Relativistic Jets as Compact Radio Sources”, Astrophys. J., 232, 34–48, (1979). [External LinkDOI].
26 Blandford, R.D., and McKee, C.F., “Fluid Dynamics of Relativistic Blast Waves”, Phys. Fluids, 19, 1130–1138, (1976). [External LinkDOI].
27 Blandford, R.D., and Payne, D.G., “Hydromagnetic flows from accretion discs and the production of radio jets”, Mon. Not. R. Astron. Soc., 199, 883–903, (1982). [External LinkADS].
28 Blandford, R.D., and Znajek, R.L., “Electromagnetic extraction of energy from Kerr black holes”, Mon. Not. R. Astron. Soc., 179, 433–456, (1977).
29 Bloom, J.S., Frail, D.A., and Sari, R., “The Prompt Energy Release of Gamma-Ray Bursts using a Cosmological k-Correction”, Astron. J., 121, 2879–2888, (2001). [External LinkDOI].
30 Bloom, J.S., Kulkarni, S.R., Djorgovski, S.G., Eichelberger, A.C., Côté, P., Blakeslee, J.P., Odewahn, S.C., Harrison, F.A., Frail, D.A., Filippenko, A.V., Leonard, D.C., Riess, A.G., Spinrad, H., Stern, D., Bunker, A., Dey, A., Grossan, B., Perlmutter, S., Knop, R.A., Hook, I.N., and Feroci, M., “The unusual afterglow of the gamma-ray burst of 26 March 1998 as evidence for a supernova connection”, Nature, 401, 453–456, (1999).
31 Bloom, J.S., Kulkarni, S.R., Price, P.A., Reichart, D., Galama, T.J., Schmidt, B.P., Frail, D.A., Berger, E., McCarthy, P.J., Chevalier, R.A., Wheeler, J.C., Halpern, J.P., Fox, D.W., Djorgovski, S.G., Harrison, F.A., Sari, R., Axelrod, T.S., Kimble, R.A., Holtzman, J., Hurley, K., Frontera, F., Piro, L., and Costa, E., “Detection of a Supernova Signature Associated with GRB 011121”, Astrophys. J. Lett., 572, L45–L49, (2002). [External LinkDOI].
32 Bonazzola, S., Frieben, J., Gourgoulhon, E., and Marck, J.-A., “Spectral methods in general relativity – toward the simulation of 3D-gravitational collapse of neutron stars”, in Ilin, A.V., and Scott, L.R., eds., ICOSAHOM ’95, Proceedings of the Third International Conference on Spectral and High Order Methods: Houston, Texas, June 5 – 9, 1995, Houston Journal of Mathematics, pp. 3–19, (University of Houston, Houston, 1996).
33 Boris, J.P., and Book, D.L., “Flux corrected transport I. SHASTA, a fluid transport algorithm that works”, J. Comput. Phys., 11, 38–69, (1973). [External LinkDOI].
34 Boris, J.P., and Book, D.L., “Flux-corrected transport III: Minimal-error FCT algorithms”, J. Comput. Phys., 20, 397–431, (1976). [External LinkDOI].
35 Boris, J.P., Book, D.L., and Hain, K., “Flux-corrected transport II: Generalizations of the method”, J. Comput. Phys., 18, 248–283, (1975).
36 Bremer, M., Krichbaum, T.P., Galama, T.J., Castro-Tirado, A.J., Frontera, F., van Paradijs, J., Mirabel, I.F., Costa, E., Hanlon, L., and Parmar, A., “Millimetre detection of GRB 970508”, Astron. Astrophys., 332, L13–L16, (1997).
37 Bridle, A., “Alan Bridle’s Image Gallery”, personal homepage, National Radio Astronomy Observatory. URL (cited on 31 January 2000):
External Link
38 Bridle, A.H., Hough, D.H., Lonsdale, C.J., Burns, J.O., and Laing, R.A., “Deep VLA Imaging of Twelve Extended 3CR Sample”, Astron. J., 108, 766–820, (1994). [External LinkDOI].
39 Briggs, M.S., Band, D.L., Kippen, R.M., Preece, R.D., Kouveliotou, C., van Paradijs, J., Share, G.H., Murphy, R.J., Matz, S.M., Connors, A., Winkler, C., McConnell, M.L., Ryan, J.M., Williams, O.R., Young, C.A., Dingus, B., Catelli, J.R., and Wijers, R.A.M.J., “Observations of GRB 990123 by the Compton Gamma-Ray Observatory”, Astrophys. J., 524, 82–91, (1999). [External LinkDOI].
40 Bugaev, K.A., Gorenstein, M.I., Kämpfer, B., and Zhdanov, V.I., “Generalized shock adiabatics and relativistic nuclear collisions”, Phys. Rev. D, 40, 2903–2913, (1989).
41 Camenzind, M., “Magnetohydrodynamics of Rotating Black Holes”, in Riffert, H., Ruder, H., Nollert, H.-P., and Hehl, F.W., eds., Relativistic Astrophysics, Vieweg Astrophysics, pp. 82–119, (Vieweg, Braunschweig; Wiesbaden, 1998).
42 Canuto, C., Hussaini, M.Y., Quarteroni, A., and Zang, T.A., Spectral Methods in Fluid Dynamics, Springer Series in Computational Physics, (Springer, Berlin; New York, 1988).
43 Carilli, C.L., Perley, R.A., Bartel, N., and Dreher, J.W., “The Jets in Cygnus A: from pc- to kpc-scales”, in Carilli, C.L., and Harris, D.E., eds., Cygnus A: Study of a Radio Galaxy, Proceedings of the Greenbank workshop, held in Greenbank, West Virginia, May 1 – 4, 1995, pp. 76–85, (Cambridge University Press, Cambridge; New York, 1996). [External LinkADS].
44 Castro-Tirado, A.J., “Cosmic Gamma-Ray Bursts: The most energetic phenomenon in the Universe”, Astrophys. Space Sci., 263, 15–26, (1999). [External Linkastro-ph/9903187].
45 Castro-Tirado, A.J., “Observations and theoretical models of gamma-ray bursts”, in Gimenez, A., Reglero, V., and Winkler, C., eds., Exploring the gamma-ray universe, Proceedings of the Fourth INTEGRAL Workshop, 4 – 8 September 2000, Alicante, Spain, ESA Special Publications, vol. 459, pp. 367–374, (ESA Publications Division, Noordwijk, 2001).
46 Cavallo, G., and Rees, M.J., “A Qualitative Study of Cosmic Fireballs and γ-Ray Bursts”, Mon. Not. R. Astron. Soc., 183, 359–365, (1978).
47 Celotti, A., “The Matter Content of Jets in Active Galactic Nuclei”, in Massaglia, S., and Bodo, G., eds., Astrophysical Jets: Open Problems, Symposium on Open Problems about Astrophysical Jets: Origin, Energy Transport and Radiation, held in Torino, Italy, December 11 – 13, 1996, pp. 79–86, (Overseas Publishers Association, Amsterdam, 1998).
48 Celotti, A., and Blandford, R.D., “On the formation of jets”, in Kaper, L., van den Heuvel, E.P.J., and Woudt, P.A., eds., Black Holes in Binaries and Galactic Nuclei, Proceedings of the ESO workshop in honour of Riccardo Giacconi, held at Garching, Germany, 6 – 8 September 1999, pp. 206–215, (Springer, Berlin; New York, 2001).
49 Celotti, A., Ghisellini, G., and Chiaberge, M., “Large-scale jets in active galactic nuclei: multiwavelength mapping”, Mon. Not. R. Astron. Soc., 321, L1–L5, (2001). [External LinkDOI].
50 Centrella, J.M., and Wilson, J.R., “Planar numerical cosmology. II. The difference equations and numerical tests”, Astrophys. J. Suppl. Ser., 54, 229–249, (1984). [External LinkDOI].
51 Chartas, G. et al., “The Chandra X-Ray Observatory Resolves the X-Ray Morphology and Spectra of a Jet in PKS 0637752”, Astrophys. J., 542, 655–666, (2000). [External LinkDOI].
52 Chorin, A.J., “Random Choice Solution of Hyperbolic Systems”, J. Comput. Phys., 22, 517–533, (1976). [External LinkDOI].
53 Chow, E., and Monaghan, J.J., “Ultrarelativistic SPH”, J. Comput. Phys., 134, 296–305, (1997). [External LinkDOI].
54 Chung, T.J., “Transitions and interactions of inviscid/viscous, compressible/incompressible and laminar/turbulent flows”, Int. J. Numer. Meth. Fl., 31, 223–246, (1999). [External LinkDOI].
55 Chung, T.J., Computational Fluid Dynamics, (Cambridge University Press, Cambridge, 2002). [External LinkGoogle Books].
56 Clare, R.B., and Strottman, D., “Relativistic hydrodynamics and heavy ion reactions”, Phys. Rep., 141, 177–280, (1986). [External LinkDOI].
57 Colella, P., “Glimm’s Method for Gas Dynamics”, SIAM J. Sci. Stat. Comput., 3, 76–110, (1982).
58 Colella, P., “Multidimensional Upwind Methods for Hyperbolic Conservation Laws”, J. Comput. Phys., 87, 171–200, (1990). [External LinkDOI].
59 Colella, P., and Glaz, H.M., “Efficient Solution Algorithms for the Riemann Problem for Real Gases”, J. Comput. Phys., 59, 264–289, (1985). [External LinkDOI].
60 Colella, P., and Woodward, P.R., “The piecewise parabolic method (PPM) for gas-dynamical simulations”, J. Comput. Phys., 54, 174–201, (1984). [External LinkDOI].
61 Costa, E., Frontera, F., Heise, J., Feroci, M., in ’t Zand, J.J.M., Fiore, F., Cinti, M.N., Dal Fiume, D., Nicastro, L., Orlandini, M., Palazzi, E., Rapisarda, M., Zavattini, G., Jager, R., Parmar, A., Owens, A., Molendi, S., Cusumano, G., Maccarone, M.C., Giarrusso, S., Coletta, A., Antonelli, L.A., Giommi, P., Muller, J.M., Piro, L., and Butler, R.C., “Discovery of an X-Ray Afterglow Associated with the γ-Ray Burst of 28 February 1997”, Nature, 387, 783–785, (1997). [External LinkDOI].
62 Courant, R., and Friedrichs, K.O., Supersonic Flow and Shock Waves, Applied Mathematical Sciences, vol. 21, (Springer, Berlin; New York, 1976). [External LinkGoogle Books].
63 Csernai, L.P., Introduction to Relativistic Heavy Ion Collisions, (Wiley, Chichester, 1994).
64 Dai, W., and Woodward, P.R., “An Iterative Riemann Solver for Relativistic Hydrodynamics”, SIAM J. Sci. Stat. Comput., 18, 982–995, (1997). [External LinkDOI].
65 Dai, W., and Woodward, P.R., “On the divergence-free condition and conservation laws in numerical simulations for supersonic magnetohydrodynamic flows”, Astrophys. J., 494, 317–335, (1998). [External LinkDOI].
66 Daigne, F., and Mochkovitch, R., “Gamma-ray bursts from internal shocks in a relativistic wind: A hydrodynamical study”, Astron. Astrophys., 358, 1157–1166, (2000).
67 Davis, R.J., Muxlow, T.W.B., and Conway, R.G., “Radio Emission from the Jet and Lobe of 3C273”, Nature, 318, 343–345, (1985). [External LinkDOI].
68 Davis, S.F., A simplified TVD finite difference scheme via artificial viscosity, ICASE Report, No. 84-20, (Institute for Computer Applications in Science and Engineering (ICASE), Hampton, VA, 1984).
69 Dean, D.J., Bottcher, C., and Strayer, M.R., “Spline Techniques for Solving Relativistic Conservation Equationstitle”, Int. J. Mod. Phys. C, 4, 723–747, (1993).
70 Dean, D.J., Bottcher, C., Strayer, M.R., Wells, J.C., von Keitz, A., Pürsün, Y., Rischke, D.H., and Maruhn, J.A., “Comparison of Flux-Correcting and Spline Algorithms for Solving (3+1)-Dimensional Relativistic Hydrodynamics”, Phys. Rev. E, 49, 1726–1733, (1994).
71 Del Zanna, L., and Bucciantini, N., “An efficient shock-capturing central-type scheme for multidimensional relativistic flows. I. Hydrodynamics”, Astron. Astrophys., 390, 1177–1186, (2002). [External LinkDOI].
72 Del Zanna, L., Bucciantini, N., and Londrillo, P., “An efficient shock-capturing central-type scheme for multidimensional relativistic flows. II. Magnetohydrodynamics”, Astron. Astrophys., 400, 397–413, (2003). [External LinkDOI], [External Linkastro-ph/0210618].
73 Djorgovski, S.G., Frail, D.A., Kulkarni, S.R., Sari, R., Bloom, J.S., Galama, T.J., Harrison, F.A., Price, P.A., Fox, D., Reichart, D.E., Yost, S.A., Berger, E., Diercks, A., Goodrich, R., and Chaffee, F., “The Cosmic Gamma-Ray Bursts”, in Gurzadyan, V.G., Jantzen, R.T., and Ruffini, R., eds., The Ninth Marcel Grossmann Meeting: On recent developments in theoretical and experimental general relativity, gravitation, and relativistic field theories, Proceedings of the MGIX MM meeting held at the University of Rome ‘La Sapienza’, 2 – 8 July 2000, pp. 315–346, (World Scientific, Singapore; River Edge, 2002).
74 Dolezal, A., and Wong, S.S.M., “Relativistic hydrodynamics and Essentially Non-Oscillatory shock capturing schemes”, J. Comput. Phys., 120, 266–277, (1995). [External LinkDOI].
75 Donat, R., Font, J.A., Ibáñez, J.M., and Marquina, A., “A Flux-Split Algorithm applied to Relativistic Flows”, J. Comput. Phys., 146, 58–81, (1998). [External LinkDOI].
76 Donat, R., and Marquina, A., “Capturing shock reflections: An improved flux formula”, J. Comput. Phys., 125, 42–58, (1996). [External LinkDOI].
77 Dubal, M.R., “Numerical Simulations of Special Relativistic, Magnetic Gas Flows”, Comput. Phys. Commun., 64, 221–234, (1991). [External LinkDOI].
78 Duncan, G.C., and Hughes, P.A., “Simulations of Relativistic Extragalactic Jets”, Astrophys. J. Lett., 436, L119–L122, (1994). [External LinkDOI].
79 Duncan, G.C., Hughes, P.A., and Opperman, J., “Simulations of relativistic extragalactic jets: A variable equation of state”, in Hardee, P.E., Bridle, A.H., and Zensus, J.A., eds., Energy Transport in Radio Galaxies and Quasars, Proceedings of a workshop, held in Tuscaloosa, Alabama, 19 – 23 September 1995, ASP Conference Series, vol. 100, pp. 143–148, (Astronomical Society of the Pacific, San Francisco, 1996).
80 Eichler, D., Livio, M., Piran, T., and Schramm, D.N., “Nucleosynthesis, Neutrino Bursts and γ-Rays from Coalescing Neutron Stars”, Nature, 340, 126–128, (1989). [External LinkDOI].
81 Einfeldt, B., “On Godunov-type methods for gas dynamics”, SIAM J. Numer. Anal., 25, 294–318, (1988). [External LinkDOI].
82 Elze, H.-T., Rafelski, J., and Turko, L., “Entropy production in relativistic hydrodynamics”, Phys. Lett., B506, 123–130, (2001).
83 Eulderink, F., Numerical relativistic hydrodynamics, Ph.D. Thesis, (Rijksuniversiteit Leiden, Leiden, 1993).
84 Eulderink, F., and Mellema, G., “General relativistic hydrodynamics with a Roe solver”, Astron. Astrophys. Suppl., 110, 587–623, (1995).
85 Evans, C.R., “An Approach for Calculating Axisymmetric Gravitational Collapse”, in Centrella, J.M., ed., Dynamical Spacetimes and Numerical Relativity, Proceedings of a workshop held at Drexel University, October 7 – 11, 1985, pp. 3–39, (Cambridge University Press, Cambridge; New York, 1986).
86 Evans, C.R., and Hawley, J.F., “Simulation of magnetohydrodynamic flows: a constrained transport method”, Astrophys. J., 332, 659–677, (1988). [External LinkDOI].
87 Falle, S.A.E.G., “Self-Similar Jets”, Mon. Not. R. Astron. Soc., 250, 581–596, (1991).
88 Falle, S.A.E.G., and Giddings, J.R., “Body capturing using adaptive cartesian grids”, in Baines, M.J., and Morton, K.W., eds., Numerical Methods for Fluid Dynamics, Proceedings of a conference held at Reading University in April 1992, pp. 335–342, (Clarendon Press; Oxford University Press, Oxford; New York, 1993). [External LinkGoogle Books].
89 Falle, S.A.E.G., and Komissarov, S.S., “An upwind numerical scheme for relativistic hydrodynamics with a general equation of state”, Mon. Not. R. Astron. Soc., 278, 586–602, (1996).
90 Fanaroff, B.L., and Riley, J.M., “The Morphology of Extragalactic Radio Sources of High and Low Luminosity”, Mon. Not. R. Astron. Soc., 167, 31–35, (1974).
91 Font, J.A., “Numerical Hydrodynamics in General Relativity”, Living Rev. Relativity, 6, lrr-2003-4, (2003). URL (cited on 6 May 2003):
92 Font, J.A., Ibáñez, J.M., Martí, J.M., and Marquina, A., “Multidimensional relativistic hydrodynamics: characteristic fields and modern high-resolution shock-capturing schemes”, Astron. Astrophys., 282, 304–314, (1994).
93 Font, J.A., Miller, M., Suen, W.-M., and Tobias, M., “Three-dimensional numerical general relativistic hydrodynamics: Formulations, methods and code tests”, Phys. Rev. D, 61, 044011, 1–26, (2000). [External Linkgr-qc/9811015].
94 Frail, D.A., Kulkarni, S.R., Nicastro, L., Feroci, M., and Taylor, G.B., “The radio afterglow from the gamma-ray burst of 8 May 1997”, Nature, 389, 261–263, (1997). [External LinkDOI].
95 Frail, D.A., Kulkarni, S.R., Sari, R., Djorgovski, S.G., Bloom, J.S., Galama, T.J., Reichart, D.E., Berger, E., Harrison, F.A., Price, P.A., Yost, S.A., Diercks, A., Goodrich, R., and Chaffee, F., “Beaming in Gamma-Ray Bursts: Evidence for a Standard Energy Reservoir”, Astrophys. J. Lett., 562, L55–L58, (2001). [External LinkDOI].
96 Freedman, D.L., and Waxman, E., “On the Energy of Gamma-Ray Bursts”, Astrophys. J., 547, 922–928, (2001). [External LinkDOI].
97 Gabuzda, D.C., Mullan, C.M., Cawthorne, T.V., Wardle, J.F.C., and Roberts, D.H., “Evolution of the Milliarcsecond Total Intensity and Polarization Structure of BL Lacertae Objects”, Astrophys. J., 435, 140–161, (1994). [External LinkDOI].
98 Galama, T.J., Vreeswijk, P.M., Pian, E., Frontera, F., Doublier, V., Gonzalez, J.-F., Lidman, C., Augusteijn, T., Hainaut, O.R., Boehnhardt, H., Patat, F., and Leibundgut, B., GRB 980425, IAU Circular, 6895, (Central Bureau for Astronomical Telegrams, Cambridge, 1998).
99 Galama, T.J., Vreeswijk, P.M., van Paradijs, J., Kouveliotou, C., Augusteijn, T., Ohnhardt, H., Brewer, J.P., Doublier, V., Gonzalez, J.-F., Leibundgut, B., Lidman, C., Hainaut, O.R., Patat, F., Heise, J., in ’t Zand, J.J.M., Hurley, K., Groot, P.J., Strom, R.G., Mazzali, P.A., Iwamoto, K., Nomoto, K., Umeda, H., Nakamura, T., Young, T.R., Suzuki, T., Shigeyama, T., Koshut, T., Kippen, M., Robinson, C., de Wildt, P., Wijers, R.A.M.J., Tanvir, N., Greiner, J., Pian, E., Palazzi, E., Frontera, F., Masetti, N., Nicastro, L., Feroci, M., Costa, E., Piro, L., Peterson, B.A., Tinney, C., Boyle, B., Cannon, R., Stathakis, R., Sadler, E., Begam, M.C., and Ianna, P., “An Unusual Supernova in the Error Box of the γ-Ray Burst of 25 April 1998”, Nature, 395, 670–672, (1998). [External LinkDOI].
100 Garnavich, P.M., Stanek, K.Z., Wyrzykowski, L., Infante, L., Bendek, E., Bersier, D., Holland, S.T., Jha, S., Matheson, T., Kirshner, R.P., Krisciunas, K., Phillips, M.M., and Carlberg, R.G., “Discovery of the Low-Redshift Optical Afterglow of GRB 011121 and Its Progenitor Supernova SN 2001ke”, Astrophys. J., 582, 924–932, (2003). [External LinkDOI], [External Linkastro-ph/0204234].
101 Germany, L.M., Reiss, D.J., Sadler, E.M., Schmidt, B.P., and Stubbs, C.W., “SN 1997cy/GRB 970514: A New Piece in the Gamma-Ray Burst Puzzle?”, Astrophys. J., 533, 320–328, (2000). [External LinkDOI].
102 Gingold, R.A., and Monaghan, J.J., “Smoothed particle hydrodynamics: theory and application to non-spherical stars”, Mon. Not. R. Astron. Soc., 181, 375–389, (1977).
103 Glaister, P., “An Approximate Linearized Riemann Solver for the Euler Equations of Gas Dynamics”, J. Comput. Phys., 74, 382–408, (1988).
104 Glimm, J., “Solutions in the large for nonlinear hyperbolic systems of equations”, Commun. Pure Appl. Math., 18, 697–715, (1965). [External LinkDOI].
105 Godunov, S.K., “Difference Methods for the Numerical Calculations of Discontinuous Solutions of the Equations of Fluid Dynamics”, Mat. Sb., 47, 271–306, (1959). In Russian, translation in: US Joint Publ. Res. Service, JPRS, 7226 (1969).
106 Gómez, J.L., “Homepage of José L. Gómez”, personal homepage, Instituto de Astrofísica de Andalucía. URL (cited on 15 December 2003):
External Link
107 Gómez, J.L., Marscher, A.P., Alberdi, A., Jorstad, S.G., and Agudo, I., “Monthly 43 GHz VLBA Polarimetric Monitoring of 3C 120 over 16 Epochs: Evidence for Trailing Shocks in a Relativistic Jet”, Astrophys. J. Lett., 561, L161–L164, (2001). [External LinkDOI].
108 Gómez, J.L., Marscher, A.P., Alberdi, A., Jorstad, S.G., and García-Miró, C., “Flashing superluminal components in the jet of the radio galaxy 3C120”, Science, 289, 2317–2320, (2000). [External LinkDOI].
109 Gómez, J.L., Marscher, A.P., Alberdi, A., Martí, J.M., and Ibáñez, J.M., “Subparsec Polarimetric Radio Observations of 3C 120: A Close-up Look at Superluminal Motion”, Astrophys. J., 499, 221–226, (1998). [External LinkDOI].
110 Gómez, J.L., Martí, J.M., Marscher, A.P., Ibáñez, J.M., and Alberdi, A., “Hydrodynammical Models of Superluminal Sources”, Astrophys. J. Lett., 482, L33–L36, (1997). [External LinkDOI].
111 Goodman, J., “Are Gamma-Ray Bursts Optically Thick?”, Astrophys. J. Lett., 308, L47–L50, (1986). [External LinkDOI].
112 Gourgoulhon, E., “1D numerical relativity applied to neutron star collapse”, Class. Quantum Grav., 9, S117–S125, (1992). [External LinkDOI], [External LinkADS].
113 Graebner, G., Relativistisches hydrodynamisches Modell hochenergetischer Kern-Kern-Stöße, Ph.D. Thesis, (Johann Wolfgang Goethe University, Frankfurt am Main, 1985).
114 Granot, J., Miller, M., Piran, T., and Suen, W.M., “Hydrodynamics and radiation from a relativistic expanding jet with applications to GRB afterglow”, in Kippen, R.M., Mallozzi, R.S., and Fishman, G.J., eds., Gamma-Ray Bursts, 5th Huntsville Symposium, Huntsville, Alabama, 18 – 22 October 1999, AIP Conference Proceedings, vol. 526, pp. 540–544, (American Institute of Physics, Melville, NY, 2000).
115 Granot, J., Miller, M., Piran, T., Suen, W.M., and Hughes, P.A., “Light curves from an expanding relativistic jet”, in Costa, E., Frontera, F., and Hjorth, J., eds., Gamma-Ray Bursts in the Afterglow Era, Proceedings of the International Workshop held in Rome, Italy, 17 – 20 October 2000, pp. 312–314, (Springer, Berlin, 2001).
116 Greiner, J., “Gamma-ray Bursts”, personal homepage, Max Planck Institute for Extraterrestrial Physics. URL (cited on 4 December 2003):
External Link
117 Hardee, P.E., “On Three-Dimensional Structures in Relativistic Hydrodynamics Jets”, Astrophys. J., 533, 176–193, (2000). [External LinkDOI].
118 Hardee, P.E., Hughes, P.A., Rosen, A., and Gómez, E.A., “Relativistic jet response to precession and wave-wave interaction”, Astrophys. J., 555, 744–757, (2001). [External LinkDOI].
119 Hardee, P.E., Rosen, A., Hughes, P.A., and Duncan, G.C., “Time-Dependent Structure of Perturbed Relativistic Jets”, Astrophys. J., 500, 599–609, (1998). [External LinkDOI].
120 Harten, A., “On a Class of High Resolution Total-Variation-Stable Finite-Difference Schemes”, SIAM J. Numer. Anal., 21, 1–23, (1984). [External LinkDOI].
121 Harten, A., Engquist, B., Osher, S., and Chakrabarthy, S.R., “Uniformly High Order Accurate Essentially Non-oscillatory Schemes, III”, J. Comput. Phys., 71, 231–303, (1987). [External LinkDOI].
122 Harten, A., Lax, P.D., and van Leer, B., “On upstream differencing and Godunov-type schemes for hyperbolic conservation laws”, SIAM Rev., 25, 35–61, (1983). [External LinkDOI].
123 Hawley, J.F., Smarr, L.L., and Wilson, J.R., “A numerical study of nonspherical black hole accretion. II. Finite differencing and code calibration”, Astrophys. J. Suppl. Ser., 55, 211–246, (1984). [External LinkDOI].
124 Hernquist, L., and Katz, N., “TREESPH: A Unification of SPH with the Hierarchical Tree Method”, Astrophys. J. Suppl. Ser., 70, 419–446, (1989). [External LinkDOI].
125 Hiscock, W.A., and Lindblom, L., “Linear Plane Waves in Dissipative Relativistic Fluids”, Phys. Rev. D, 35, 3723–3732, (1987).
126 Homan, D.C., and Wardle, J.F.C., “Detection and measurement of parsec-scale circular polarization in four AGNs”, Astron. J., 118, 1942–1962, (1999). [External LinkDOI].
127 Howell, L.H., and Greenough, J.A., “Radiation diffusion for multi-fluid Eulerian hydrodynamics with adaptive mesh refinement”, J. Comput. Phys., 184, 53–78, (2003). [External LinkDOI].
128 Hughes, P.A., Miller, M.A., and Duncan, G.C., “Three-dimensional hydrodynamic simulations of relativistic extragalactic jets”, Astrophys. J., 572, 713–728, (2002). [External LinkDOI].
129 Inutsuka, S., “Reformulation of smoothed particle hydrodynamics with Riemann Solver”, J. Comput. Phys., 179, 238–267, (2002). [External LinkDOI].
130 Israel, W., “Covariant fluid mechanics and thermodynamics: An introduction”, in Anile, A., and Choquet-Bruhat, Y., eds., Relativistic Fluid Dynamics, Lectures given at the 1st 1987 session of the Centro Internazionale Matematico Estivo (C.I.M.E.) held at Noto, Italy, May 25 – June 3, 1987, Lecture Notes in Mathematics, vol. 1385, pp. 152–210, (Springer, Berlin; New York, 1989).
131 Iwamoto, T.J., Mazzali, P.A., Nomoto, K., Umeda, H., Nakamura, T., Patat, F., Danziger, I.J., Young, T.R., Suzuki, T., Shigeyama, T., Augusteijn, T., Doublier, V., Gonzalez, J.-F., Boehnhardt, H., Brewer, J.P., Hainaut, O.R., Lidman, C., Leibundgut, B., Cappellaro, E., Turatto, M., Galama, T.J., Vreeswijk, P.M., Kouveliotou, C., van Paradijs, J., Pian, E., Palazzi, E., and Frontera, F., “A Hypernova Model for the Supernova Associated with the γ-Ray Burst of 25 April 1998”, Nature, 395, 672–674, (1998).
132 Jenny, P., and Müller, B., “Rankine–Hugoniot–Riemann Solver Considering Source Terms and Multidumensional Effects”, J. Comput. Phys., 145, 575–610, (1998). [External LinkDOI].
133 Junor, W., Biretta, J.A., and Livio, M., “Formation of the radio jet in M87 at 100 Scharzschild radii from the central black hole”, Nature, 401, 891–892, (1999).
134 Kheyfets, A., Miller, W.A., and Zurek, W.H., “Covariant smoothed particle hydrodynamics on a curved background”, Phys. Rev. D, 41, 451–454, (1990).
135 Kobayashi, S., Piran, T., and Sari, R., “Hydrodynamics of a Relativistic Fireball: The Complete Evolution”, Astrophys. J., 513, 669–678, (1999). [External LinkDOI].
136 Koide, S., “A Two-dimensional Simulation of a Relativistic Jet bent by an Oblique Magnetic Field”, Astrophys. J., 487, 66–69, (1997). [External LinkDOI].
137 Koide, S., Meier, D.L., Shibata, K., and Kudoh, T., “General relativistic simulations of early jet formation in a rapidly rotating black hole magnetosphere”, Astrophys. J., 536, 668–674, (2000). [External LinkDOI].
138 Koide, S., Nishikawa, K.-I., and Mutel, R.L., “A Two-Dimensional Simulation of a Relativistic Magnetized Jet”, Astrophys. J., 463, L71–L74, (1996). [External LinkDOI].
139 Koide, S., Shibata, K., and Kudoh, T., “General relativistic magnetohydrodynamic simulations of jets from black hole accretion disks: Two-component jets driven by nonsteady accretion of magnetized disks”, Astrophys. J. Lett., 495, L63–L66, (1998). [External LinkDOI].
140 Koide, S., Shibata, K., and Kudoh, T., “Relativistic Jet Formation from Black Hole Magnetized Accretion Disks: Method, Tests, and Applications of a General Relativistic Magnetohydrodynamical Numerical Code”, Astrophys. J., 522, 727–752, (1999). [External LinkDOI].
141 Koide, S., Shibata, K., Kudoh, T., and Meier, D.L., “Numerical method for General Relativistic Magnetohydrodynamics in Kerr-Space-Time”, J. Korean Astron. Soc., 34, S215–S224, (2001).
142 Koide, S., Shibata, K., Kudoh, T., and Meier, D.L., “Extraction of black hole rotational energy by a magnetic field and the formation of relativistic jets”, Science, 295, 1688–1691, (2002). [External LinkDOI].
143 Komissarov, S.S., “A Godunov-Type Scheme for Relativistic Magnetohydrodynamics”, Mon. Not. R. Astron. Soc., 303, 343–366, (1999). [External LinkDOI].
144 Komissarov, S.S., “Numerical simulations of relativistic magnetized jets”, Mon. Not. R. Astron. Soc., 308, 1069–1076, (1999). [External LinkDOI].
145 Komissarov, S.S., “Direct simulations of the Blandford–Znajek effect”, Mon. Not. R. Astron. Soc., 326, L41–L44, (2001). [External LinkDOI].
146 Komissarov, S.S., “Time-dependent, force-free, degenerate electrodynamics”, Mon. Not. R. Astron. Soc., 336, 759–766, (2002). [External LinkDOI], [External Linkastro-ph/0202447].
147 Komissarov, S.S., and Falle, S.A.E.G., “Simulations of Superluminal Sources”, Mon. Not. R. Astron. Soc., 288, 833–848, (1997).
148 Komissarov, S.S., and Falle, S.A.E.G., “The Large Scale Structure of FR-II Radio Sources”, Mon. Not. R. Astron. Soc., 297, 1087–1108, (1998). [External LinkDOI].
149 Kulkarni, S.R., Frail, D.A., Wieringa, M.H., Ekers, R.D., Sadler, E.M., Wark, R.M., Higdon, J.L., Phinney, E.S., and Bloom, J.S., “Radio Emission from the Supernova 1998bw and its Association with the γ-Ray Burst of 25 April 1998”, Nature, 395, 663–669, (1998).
150 Laguna, P., Miller, W.A., and Zurek, W.H., “Smoothed particle hydrodynamics near a black hole”, Astrophys. J., 404, 678–685, (1993). [External LinkDOI].
151 Lahy, N.K., A Particle Method for Relativistic Fluid Dynamics, Masters Thesis, (Monash University, Melbourne, Australia, 1989).
152 Laing, R.A., “Brightness and Polarization Structure of Decelerating Relativistic Jets”, in Hardee, P.E., Bridle, A.H., and Zensus, J.A., eds., Energy Transport in Radio Galaxies and Quasars, Proceedings of a workshop held in Tuscaloosa, Alabama, 19 – 23 September 1995, ASP Conference Series, vol. 100, pp. 241–252, (Astronomical Society of the Pacific, San Francisco, 1996).
153 Landau, L.D., and Lifshitz, E.M., Fluid Mechanics, (Pergamon, New York, 1987).
154 Laney, C.B., Computational Gasdynamics, (Cambridge University Press, Cambridge; New York, 1998). [External LinkGoogle Books].
155 Lattanzio, J.C., Monaghan, J.J., Pongracic, H., and Schwarz, H.P., “Controlling Penetration”, SIAM J. Sci. Stat. Comput., 7, 591–598, (1986).
156 Lax, P.D., and Wendroff, B., “Systems of conservation laws”, Commun. Pure Appl. Math., 13, 217–237, (1960). [External LinkDOI].
157 LeVeque, R.J., Numerical Methods for Conservation Laws, (Birkhäuser, Basel; Boston, 1992), 2nd edition. [External LinkGoogle Books].
158 LeVeque, R.J., “Wave propagation algorithms for multi-dimensional hyperbolic systems”, J. Comput. Phys., 131, 327–353, (1997). [External LinkDOI].
159 LeVeque, R.J., “Balancing Source Terms and Flux Gradients in High Resolution Godunov Methods”, J. Comput. Phys., 146, 346–365, (1998). [External LinkDOI].
160 LeVeque, R.J., “Nonlinear Conservation Laws and Finite Volume Methods”, in LeVeque, R.J., Mihalas, D., Dorfi, E.A., Müller, E., Steiner, O., and Gautschy, A., eds., Computational Methods for Astrophysical Fluid Flow, Lecture Notes of the Saas-Fee Advanced Course 27, Les Diablerets, Switzerland, March 3 – 8, 1997, Saas-Fee Advanced Courses, vol. 27, pp. 1–159, (Springer, Berlin; New York, 1998).
161 LeVeque, R.J., and Berger, M., “AMR CLAWPACK”, project homepage, University of Washington. URL (cited on 13 December 2002):
External Link
162 LeVeque, R.J., Mihalas, D., Dorfi, E.A., Müller, E., Steiner, O., and Gautschy, A., eds., Computational Methods for Astrophysical Fluid Flow, Lecture Notes of the Saas-Fee Advanced Course 27, Les Diablerets, Switzerland, March 3 – 8, 1997, Saas-Fee Advanced Courses, vol. 27, (Springer, Berlin; New York, 1998).
163 Lichnerowicz, A., Relativistic hydrodynamics and magnetohydrodynamics, (Benjamin, New York, 1967).
164 Liu, X.D., and Osher, S., “Convex ENO high order multi-dimensional schemes without field by field decomposition or staggered grids”, J. Comput. Phys., 142, 304–330, (1998). [External LinkDOI].
165 Lobanov, A.P., Krichbaum, T.P., Witzel, A., Kraus, A., Zensus, J.A., Britzen, S., Otterbein, K., Hummel, C.A., and Johnston, K., “VSOP imaging of S5 0836+710: a close-up on plasma instabilities in the jet”, Astron. Astrophys., 340, L60–L64, (1998).
166 Lobanov, A.P., and Zensus, J.A., “A Cosmic double helix in the archetypical Quasar 3C273”, Science, 294, 128–131, (2001). [External LinkDOI].
167 Lombardi Jr, J.C., Sills, A., Rasio, F.A., and Shapiro, S.L., “Tests of spurious transport in smoothed particle hydrodynamics”, J. Comput. Phys., 152, 687–735, (1999). [External LinkDOI].
168 Lucy, L.B., “A numerical approach to the testing of the fission hypothesis”, Astron. J., 82, 1013–1024, (1977). [External LinkDOI].
169 MacFadyen, A.I., and Woosley, S.E., “Collapsars: Gamma-ray bursts and explosions in ‘failed supernovae”’, Astrophys. J., 524, 262–289, (1999). [External LinkDOI], [External Linkastro-ph/9810274].
170 MacFadyen, A.I., Woosley, S.E., and Heger, A., “Supernovae, Jets, and Collapsars”, Astrophys. J., 550, 410–425, (2001). [External LinkDOI].
171 MacNeice, P., and Olson, K., “PARAMESH: Parallel Adaptive Mesh Refinement”, project homepage, NASA Goddard Space Flight Center and Drexel University. URL (cited on 11 November 2009):
External Link
172 Mann, P.J., “A relativistic smoothed particle hydrodynamics method tested with the shock tube”, Comput. Phys. Commun., 67, 245–260, (1991). [External LinkDOI].
173 Mann, P.J., “A Finite Element Method in Space and Time for Relativistic Spherical Collapse”, Comput. Phys. Commun., 75, 10–30, (1993). [External LinkDOI].
174 Mann, P.J., “Smoothed Particle Hydrodynamics Applied to Relativistic Spherical Collapse”, Comput. Phys. Commun., 107, 188–198, (1993).
175 Marquina, A., “Local Piecewise Hyperbolic Reconstruction of Numerical Fluxes for Nonlinear Scalar Conservation Laws”, SIAM J. Sci. Stat. Comput., 15, 892–915, (1994). [External LinkDOI].
176 Marquina, A., Martí, J.M., Ibáñez, J.M., Miralles, J.A., and Donat, R., “Ultrarelativistic Hydrodynamics: High-Resolution Shock-Capturing Methods”, Astron. Astrophys., 258, 566–571, (1992).
177 Marscher, A.P., and Gear, W.K., “Models for high-frequency radio outbursts in extragalactic sources, with application to the early 1983 millimeter-to-infrared flare of 3C 273”, Astrophys. J., 298, 114–127, (1985). [External LinkDOI].
178 Marscher, A.P., Jorstad, S.G., Gómez, J.L., Aller, M.F., Teräsranta, H., Lister, M.L., and Stirling, A.M., “Observational evidence for the accretion-disk origin for a radio jet in an active galaxy”, Nature, 417, 625–627, (2002). [External LinkDOI].
179 Martí, J.M., Ibáñez, J.M., and Miralles, J.A., “Numerical relativistic hydrodynamics: Local characteristic approach”, Phys. Rev. D, 43, 3794–3801, (1991).
180 Martí, J.M., and Müller, E., “The analytical solution of the Riemann problem in relativistic hydrodynamics”, J. Fluid Mech., 258, 317–333, (1994). [External LinkDOI].
181 Martí, J.M., and Müller, E., “Extension of the piecewise parabolic method to one-dimensional relativistic hydrodynamics”, J. Comput. Phys., 123, 1–14, (1996). [External LinkDOI].
182 Martí, J.M., Müller, E., Font, J.A., and Ibáñez, J.M., “Morphology and Dynamics oh Highly Supersonic Relativistic Jets”, Astrophys. J., 448, L105–L108, (1995). [External LinkDOI].
183 Martí, J.M., Müller, E., Font, J.A., Ibáñez, J.M., and Marquina, A., “Morphology and dynamics of relativistic jets”, Astrophys. J., 479, 151–163, (1997). [External LinkDOI].
184 Martí, J.M., Müller, E., and Ibáñez, J.M., “Hydrodynamical Simulations of Relativistic Jets”, Astron. Astrophys., 281, L9–L12, (1994).
185 Mazzali, P.A., Deng, J., Maeda, K., Nomoto, K., Umeda, H., Hatano, K., Iwamoto, K., Yoshii, Y., Kobayashi, Y., Minezaki, T., Doi, M., Enya, K., Tomita, H., Smartt, S.J., Kinugasa, K., Kawakita, H., Ayani, K., Kawabata, T., Yamaoka, H., Qiu, Y.L., Motohara, K., Gerardy, C.L., Fesen, R., Kawabata, K.S., Iye, M., Kashikawa, N., Kosugi, G., Ohyama, Y., Takada-Hidai, M., Zhao, G., Chornock, R., Filippenko, A.V., Benetti, S., and Turatto, M., “The Type Ic Hypernova SN2002ap”, Astrophys. J. Lett., 572, L61–L65, (2002). [External LinkDOI].
186 Mazzali, P.A., Iwamoto, K., and Nomoto, K., “A Spectroscopic Analysis of the Energetic Type Ic Hypernova SN 1997ef”, Astrophys. J., 545, 407–419, (2000). [External LinkDOI].
187 McAbee, T.L., Wilson, J.R., Zingman, J.A., and Alonso, C.T., “Hydrodynamic Simulations of 16O + 208Pb Collisions at 200 GeV/N”, Mod. Phys. Lett. A, 4, 983–993, (1989).
188 Meegan, C.A., Fishman, G.J., Wilson, R.B., Horack, J.M., Brock, M.N., Paciesas, W.S., Pendleton, G.N., and Kouveliotou, C., “Spatial Distribution of γ-Ray Bursts Observed by BATSE”, Nature, 355, 143–145, (1992). [External LinkDOI].
189 Meier, D.L., “The association of jet production with geometrically thick accretion flows and black hole rotation”, Astrophys. J. Lett., 548, L9–L12, (2000).
190 Meier, D.L., Koide, S., and Uchida, Y., “Magnetohydrodynamic production of relativistic jets”, Science, 291, 84–92, (2001). [External LinkDOI].
191 Menikoff, R., and Plohr, B.J., “The Riemann problem for fluid flow of real materials”, Rev. Mod. Phys., 61, 75–130, (1989).
192 Mészáros, P., “Theories of gamma-ray bursts”, Annu. Rev. Astron. Astrophys., 40, 137–169, (2002). [External LinkDOI].
193 Metzger, M.R., Djorgovski, S.G., Kulkarni, S.R., Steidel, C.C., Adelberger, K.L., Frail, D.A., Costa, E., and Frontera, F., “Spectral Constraints on the Redshift of the Optical Counterpart to the γ-Ray Burst of the 8 May 1997”, Nature, 387, 878–880, (1997). [External LinkDOI].
194 Mioduszewski, A.J., Hughes, P.A., and Duncan, G.C., “Simulated VLBI Images from Relativistic Hydrodynamic Jet Models”, Astrophys. J., 476, 649–665, (1997). [External LinkDOI].
195 Mirabel, I.F., and Rodriguez, L.F., “A Superluminal Source in the Galaxy”, Nature, 371, 46–48, (1994). [External LinkDOI].
196 Mizuta, A., Yamada, S., and Takabe, H., “Numerical study of AGN jet propagation with two dimensional relativistic hydrodynamic code”, J. Korean Astron. Soc., 34, 329–331, (2001).
197 Mochkovitch, R., Hernanz, M., Isern, J., and Martin, X., “Gamma-ray bursts as collimated jets from neutron star/black hole mergers”, Nature, 361, 236–238, (1993). [External LinkDOI].
198 Monaghan, J.J., “Particle Methods for Hydrodynamics”, Comput. Phys. Rep., 3, 71–124, (1985). [External LinkDOI].
199 Monaghan, J.J., “Smoothed particle hydrodynamics”, Annu. Rev. Astron. Astrophys., 30, 543–574, (1992). [External LinkDOI].
200 Monaghan, J.J., “SPH and Riemann Solvers”, J. Comput. Phys., 136, 298–307, (1997). [External LinkDOI].
201 Monaghan, J.J., and Lattanzio, J.C., “A Refined Particle Method for Astrophysical Problems”, Astron. Astrophys., 149, 135–143, (1985).
202 Monaghan, J.J., and Price, D.J., “Variational principles for relativistic smoothed particle hydrodynamics”, Mon. Not. R. Astron. Soc., 328, 381–392, (2001). [External LinkDOI].
203 Morris, J.P., and Monaghan, J.J., “A switch to reduce SPH viscosity”, J. Comput. Phys., 136, 41–50, (1997). [External LinkDOI].
204 Muir, S., GR SPH, Ph.D. Thesis, (Monash University, Melbourne, Australia, 2002).
205 Müller, E., “Simulation of Astrophysical Fluid Flow”, in LeVeque, R.J., Mihalas, D., Dorfi, E.A., Müller, E., Steiner, O., and Gautschy, A., eds., Computational Methods for Astrophysical Fluid Flow, Lecture Notes of the Saas-Fee Advanced Course 27, Les Diablerets, Switzerland, March 3 – 8, 1997, Saas-Fee Advanced Courses, vol. 27, pp. 343–494, (Springer, Berlin; New York, 1998).
206 Nakamura, T., “General Relativistic Collapse of Axially Symmetric Stars Leading to the Formation of Rotating Black Holes”, Prog. Theor. Phys., 65, 1876–1890, (1981). [External LinkDOI].
207 Nakamura, T., “General Relativistic Collapse of Axially Symmetric Stars Leading to the Formation of Rotating Black Holes”, Prog. Theor. Phys., 65, 1876–1890, (1981). [External LinkDOI].
208 Nakamura, T., Maeda, K., Miyama, S.M., and Sasaki, M., “General Relativistic Collapse of an Axially Symmetric Star. I”, Prog. Theor. Phys., 63, 1229–1244, (1980). [External LinkDOI].
209 Nakamura, T., and Sato, H., “General Relativistic Collapse of Non-Rotating, Axisymmetric Stars”, Prog. Theor. Phys., 67, 1396–1405, (1982). [External LinkDOI], [External LinkADS].
210 Nishikawa, K.-I., Koide, S., Sakai, J.-I., Christodoulou, D.M., Sol, H., and Mutel, R.L., “Three-Dimensional Magnetohydrodynamic Simulations of Relativistic Jets Injected along a Magnetic Field”, Astrophys. J., 483, L45–L48, (1997). [External LinkDOI].
211 Nishikawa, K.-I., Koide, S., Sakai, J.-I., Christodoulou, D.M., Sol, H., and Mutel, R.L., “Three-Dimensional Magnetohydrodynamic Simulations of Relativistic Jets Injected into an Oblique Magnetic Field”, Astrophys. J., 498, 166–169, (1998). [External LinkDOI].
212 Nishikawa, K.-I., Koide, S., Shibata, K., Kudoh, T., and Sol, H., “3-D General Relativistic MHD Simulations of Generating Jets”, in Laing, R.A., and Blundell, K.M., eds., Particles and Fields in Radio Galaxies, Proceedings of the Oxford Radio Galaxy Workshop held at Oxford University, Department of Astrophysics, Oxford, United Kingdom, 3 – 5 August 2000, ASP Conference Series, vol. 250, p. 22, (Astronomical Society of the Pacific, San Franciso, 2001). [External Linkastro-ph/0202396].
213 Noh, W.F., “Errors for calculations of strong shocks using an artificial viscosity and an artificial heat flux”, J. Comput. Phys., 72, 78–120, (1987). [External LinkDOI].
214 Norman, M.L., and Winkler, K.-H.A., “Why Ultrarelativistic Numerical Hydrodynamics is Difficult”, in Winkler, K.-H.A., and Norman, M.L., eds., Astrophysical Radiation Hydrodynamics, Proceedings of the NATO Advanced Research Workshop, Garching, Germany, August 2 – 13, 1982, NATO ASI Series C, vol. 188, pp. 449–475, (Reidel, Dordrecht; Boston, 1986).
215 Oran, E.S., and Boris, J.P., Numerical Simulations of Reactive Flow, (Elsevier, New York, 1987). [External LinkGoogle Books].
216 Osher, S., and Chakravarthy, S., “High Resolution Schemes and the Entropy Condition”, SIAM J. Numer. Anal., 21, 955–984, (1984). [External LinkDOI].
217 Paczyński, B., “Gamma-ray bursters at cosmological distances”, Astrophys. J. Lett., 308, L43–L46, (1986).
218 Paczyński, B., “Are Gamma-Ray Bursts in Star Forming Regions?”, Astrophys. J. Lett., 494, L45–L48, (1998). [External LinkDOI].
219 Panaitescu, A., and Kumar, P., “Properties of Relativistic Jets in Gamma-Ray Burst Afterglows”, Astrophys. J., 571, 779–789, (2002). [External LinkDOI].
220 Panaitescu, A., Wen, L., Laguna, P., and Mészáros, P., “Impact of Relativistic Fireballs on External Matter: Numerical Models of Cosmological Gamma-Ray Bursts”, Astrophys. J., 482, 942–950, (1997). [External LinkDOI].
221 Papadopoulos, P., and Font, J.A., “Relativistic hydrodynamics on spacelike and null surfaces: Formalism and computations of spherically symmetric spacetimes”, Phys. Rev. D, 61, 024015, 1–15, (2000). [External LinkDOI], [External LinkADS].
222 Peitz, J., and Appl, S., “3+1 Formulation of Non-Ideal Hydrodynamics”, Mon. Not. R. Astron. Soc., 296, 231–244, (1998). [External LinkDOI].
223 Pian, E., Amati, L., Antonelli, L.A., Butler, R.C., Costa, E., Cusumano, G., Danziger, I.J., Feroci, M., Fiore, F., Frontera, F., Giommi, P., Masetti, N., Muller, J.M., Oosterbroek, T., Owens, A., Palazzi, E., Piro, L., Castro-Tirado, A.J., Coletta, A., Dal Fiume, D., Del Sordo, S., Heise, J., Nicastro, L., Orlandini, M., Parmar, A.N., Soffitta, P., Torroni, V., and in ’t Zand, J.J.M., “BeppoSAX detection and follow-up of GRB 980425”, Astron. Astrophys. Suppl., 138, 463–464, (1999). [External LinkDOI], [External Linkastro-ph/9903113].
224 Piran, T., “Numerical Codes for Cylindrical General Relativistic Systems”, J. Comput. Phys., 35, 254–283, (1980). [External LinkDOI], [External LinkADS].
225 Piran, T., “Gamma-Ray Bursts and the Fireball Model”, Phys. Rep., 314, 575–667, (1999). [External LinkDOI].
226 Piran, T., “Gamma-ray bursts – A puzzle being resolved”, Phys. Rep., 333-334, 529–553, (2000). [External LinkDOI].
227 Piran, T., “Gamma-Ray Bursts – When theory meets observations”, in Wheeler, J.C., and Martel, H., eds., Relativistic Astrophysics, 20th Texas Symposium, Austin, Texas, 10 – 15 December 2000, AIP Conference Proceedings, vol. 586, pp. 575–586, (American Institut of Physics, Melville, NY, 2001).
228 Piran, T., Shemi, A., and Narayan, R., “Hydrodynamics of Relativistic Fireballs”, Mon. Not. R. Astron. Soc., 263, 861–867, (1993).
229 Piro, L., Heise, J., Jager, R., Costa, E., Frontera, F., Feroci, M., Muller, J.M., Amati, L., Cinti, M.N., Dal Fiume, D., Nicastro, L., Orlandini, M., and Pizzichini, G., “The First X-Ray Localization of a γ-Ray Burst by BeppoSAX and its Fast Spectral Evolution”, Astron. Astrophys., 329, 906–910, (1998).
230 Plewa, T., “Adaptive Mesh Refinement for structured grids”, personal homepage, University of Chicago. URL (cited on 11 November 2009):
External Link
231 Plewa, T., and Martí, J.M., “RJET – Evolution of Relativistic Jets”, project homepage, Nicolaus Copernicus Astronomical Centre. URL (cited on 11 November 2009):
External Link
232 Plewa, T., Martí, J.M., Müller, E., Różycka, M., and Sikora, M., “Bending Relativistic Jets in AGNs”, in Ostrowski, M., Sikora, M., Madejski, G., and Begelman, M., eds., Relativistic Jets in AGNs, pp. 104–109, (Jagiellonian University, Kraków, 1997).
233 Plewa, T., and Müller, E., “The Consistent Multi-Fluid Advection Method”, Astron. Astrophys., 342, 179–191, (1999).
234 Pons, J.A., Font, J.A., Ibáñez, J.M., Martí, J.M., and Miralles, J.A., “General Relativistic Hydrodynamics with Special Relativistic Riemann Solvers”, Astron. Astrophys., 339, 638–642, (1998).
235 Pons, J.A., Martí, J.M., and Müller, E., “The exact solution of the Riemann problem with non-zero tangential velocities in relativistic hydrodynamics”, J. Fluid Mech., 422, 125–139, (2000). [External LinkDOI].
236 Popham, R., Woosley, S.E., and Fryer, C., “Hyper-accreting black holes and gamma-ray bursts”, Astrophys. J., 518, 356–374, (1998).
237 Potter, D., Computational Physics, (Wiley, Chichester, 1977).
238 Price, P.A., Berger, E., Reichart, D.E., Kulkarni, S.R., Yost, S.A., Subrahmanyan, R., Wark, R.M., Wieringa, M.H., Frail, D.A., Bailey, J., Boyle, B., Corbett, E., Gunn, K., Ryder, S.D., Seymour, N., Koviak, K., McCarthy, P., Phillips, M.M., Axelrod, T.S., Bloom, J.S., Djorgovski, S.G., Fox, D.W., Galama, T.J., Harrison, F.A., Hurley, K., Sari, R., Schmidt, B.P., Brown, M.J.I., Cline, T., Frontera, F., Guidorzi, C., and Montanari, E., “GRB 011121: A Massive Star Progenitor”, Astrophys. J. Lett., 572, L51–L55, (2002). [External LinkDOI].
239 Quirk, J.J., “A contribution to the great Riemann solver debate”, Int. J. Numer. Meth. Fluids, 18, 555–574, (1994). [External LinkDOI].
240 Reeves, J.N., Watson, D., Osborne, J.P., Pounds, K.A., O’Brien, P.T., Short, A.D.T., Turner, M.J.L., Watson, M.G., Mason, K.O., Ehle, M., and Schartel, N., “The signature of supernova ejecta in the X-ray afterglow of the gamma-ray burst 011211”, Nature, 416, 512–515, (2002). [External LinkDOI].
241 Rezzolla, L., and Zanotti, O., “An improved exact Riemann solver for relativistic hydrodynamics”, J. Fluid Mech., 449, 395–411, (2001). [External LinkDOI].
242 Rezzolla, L., Zanotti, O., and Pons, J.A., “An Improved Exact Riemann Solver for Multidimensional Relativistic Flows”, J. Fluid Mech., 479, 199–219, (2003). [External LinkDOI], [External Linkgr-qc/0205034].
243 Richardson, G.A., and Chung, T.J., “Computational relativistic astrophysics using the flow field-dependent variation theory”, Astrophys. J. Suppl. Ser., 139, 539–563, (2002). [External LinkDOI].
244 Richtmyer, R.D., and Morton, K.W., Difference methods for initial-value problems, Interscience Tracts in Pure and Applied Mathematics, vol. 4, (Interscience, New York, 1967), 2nd edition.
245 Rischke, D.H., Bernhard, S., and Maruhn, J.A., “Relativistic hydrodynamics for heavy-ion collisions: I. General aspects and expansion into vacuum”, Nucl. Phys. A, 595, 346–382, (1995). [External LinkDOI].
246 Rischke, D.H., and Gyulassy, M., “The time-delay signature of quark-gluon plasma formation in relativistic nuclear collisions”, Nucl. Phys. A, 608, 479–512, (1996). [External LinkDOI].
247 Rischke, D.H., Pürsün, Y., and Maruhn, J.A., “Relativistic hydrodynamics for heavy-ion collisions: II. Compression of nuclear matter and the phase transition to the quark-gluon plasma”, Nucl. Phys. A, 595, 383–408, (1995). [External LinkDOI].
248 Roe, P.L., “Approximate Riemann solvers, parameter vectors and difference schemes”, J. Comput. Phys., 43, 357–372, (1981). [External LinkDOI].
249 Roe, P.L., Generalized formulation of TVD Lax–Wendroff schemes, ICASE Report, No. 84-53, (Institute for Computer Applications in Science and Engineering (ICASE), Hampton, VA, 1984).
250 Romero, J.V., Ibáñez, J.M., Martí, J.M., and Miralles, J.A., “A new spherically symmetric general relativistic hydrodynamical code”, Astrophys. J., 462, 839–854, (1996). [External LinkDOI].
251 Romero, R., Ibáñez, J.M., Martí, J.M., and Miralles, J.A., “Relativistic Magnetohydrodynamics: Analytical and Numerical Aspects”, in Miralles, J.A., Morales, J.A., and Sáez, D., eds., Some Topics on General Relativity and Gravitational Radiation, Proceedings of the Spanish Relativity Meeting ’96, Valencia, 10 – 13 September 1996, pp. 145–148, (Editions Frontières, Paris, 1997).
252 Rosen, A., Hughes, P.A., Duncan, G.C., and Hardee, P.E., “A comparison of the morphology and stability of relativistic and nonrelativistic jets”, Astrophys. J., 516, 729–743, (1999). [External LinkDOI].
253 Ryu, D., Miniati, F., Jones, T.W., and Frank, A., “A divergence-free upwind code for multidimensional magnetohydrodynamic flows”, Astrophys. J., 509, 244–255, (1998). [External LinkDOI].
254 Sanders, R.H., and Prendergast, K.H., “The Possible Relation of the 3-Kiloparsec Arm to Explosions in the Galactic Nucleus”, Astrophys. J., 188, 489–500, (1974). [External LinkDOI].
255 Sari, R., Piran, T., and Halpern, J.P., “Jets in Gamma-Ray Bursts”, Astrophys. J. Lett., 519, L17–L20, (1999). [External LinkDOI].
256 Scheck, L., Aloy, M.A., Martí, J.M., Gómez, J.L., and Müller, E., “Does the plasma composition affect the long-term evolution of relativistic jets”, Mon. Not. R. Astron. Soc., 331, 615–634, (2002). [External LinkDOI].
257 Schneider, V., Katscher, V., Rischke, D.H., Waldhauser, B., Marhun, J.A., and Munz, C.-D., “New algorithms for ultra-relativistic numerical hydrodynamics”, J. Comput. Phys., 105, 92–107, (1993). [External LinkDOI].
258 Selhammar, M., “Modified artificial viscosity in smoothed particle hydrodynamics”, Astron. Astrophys., 325, 857–865, (1997).
259 Shu, C.W., “TVB uniformly high-order schemes for conservation laws”, Math. Comput., 49, 105–121, (1987). [External LinkDOI].
260 Shu, C.W., and Osher, S., “Efficient implementation of essentially non-oscillatory shock-capturing schemes”, J. Comput. Phys., 77, 439–471, (1988). [External LinkDOI].
261 Shu, C.W., and Osher, S., “Efficient Implementation of Essentially Non-Oscillatory Shock-Capturing Schemes, II”, J. Comput. Phys., 83, 32–78, (1989). [External LinkDOI].
262 Siegler, S., and Riffert, H., “Smoothed Particle Hydrodynamics Simulations of Ultrarelativistic Shocks with Artificial Viscosity”, Astrophys. J., 531, 1053–1066, (2000). [External LinkDOI], [External Linkastro-ph/9904070].
263 Sikora, M., and Madejski, G., “On Pair Content and Variability of Subparsec Jets in Quasars”, Astrophys. J., 534, 109–113, (2000). [External LinkDOI].
264 Soffitta, P., Feroci, M., Pior, L., in ’t Zand, J.J.M., Heise, J., DiCiolo, L., Muller, J.M., Palazzi, E., and Frontera, F., GRB 980425, IAU Circular, 6884, (Central Bureau for Astronomical Telegrams, Cambridge, 1998).
265 Sokolov, I.V., Timofeev, E., Sakai, J.-I., and Takayama, K., “Development and applications of artificial wind schemes for hydrodynamics, MHD and relativistic hydrodynamics”, in Proceedings of the 13th National CFD Symposium, Chuo University, Tokyo, Japan, December 21–23, 1999 (CD-ROM), pp. E1–E05, (1999).
266 Sokolov, I.V., Zhang, H.-M., and Sakai, J.-I., “Simple and efficient Godunov Scheme for Computational Relativistic Gas Dynamics”, J. Comput. Phys., 172, 209–234, (2001). [External LinkDOI].
267 Sol, H., Pelletier, G., and Asséo, E., “Two-flow model for extragalactic radio jets”, Mon. Not. R. Astron. Soc., 237, 411–429, (1989).
268 Stark, R.F., and Piran, T., “A general relativistic code for rotating axisymmetric configurations and gravitational radiation: Numerical methods and tests”, Comput. Phys. Rep., 5, 221–264, (1987). [External LinkDOI].
269 Steinmetz, M., and Müller, E., “On the Capabilities and Limits of Smoothed Particle Hydrodynamics”, Astron. Astrophys., 268, 391–410, (1993).
270 Strang, G., “On the construction and comparison of difference schemes”, SIAM J. Numer. Anal., 5, 506–517, (1968). [External LinkDOI].
271 Swegle, J.W., Hicks, D.L., and Attaway, S.W., “Smoothed Particle Hydrodynamics Stability Analysis”, J. Comput. Phys., 116, 123–134, (1995). [External LinkDOI].
272 Synge, J.L., The Relativistic Gas, (North-Holland; Interscience, Amsterdam; New York, 1957).
273 Tan, J.C., Matzner, C.D., and McKee, C.F., “Trans-relativistic blast waves in supernovae as gamma-ray burst progenitors”, Astrophys. J., 551, 946–972, (2001). [External LinkDOI].
274 Taub, A.H., “Relativistic Fluid Mechnaics”, Annu. Rev. Fluid Mech., 10, 301–332, (1978). [External LinkDOI].
275 Thacker, R.J., Tittley, E.R., Pearce, F.R., Couchman, H.M.P., and Thomas, P.A., “Smoothed particle hydrodynamics in cosmology: A comparative study of implementations”, Mon. Not. R. Astron. Soc., 319, 619–648, (2000). [External LinkDOI].
276 Thompson, K.W., “The Special Relativistic Shock Tube”, J. Fluid Mech., 171, 365–375, (1986). [External LinkDOI].
277 Tingay, S.J., Jauncey, D.L., Preston, R.A., Reynolds, J.E., Meier, D.L., Murphy, D.W., Tzioumis, A.K., Mckay, D.J., Kesteven, M.J., Lovell, J.E.J., Campbell-Wilson, D., Ellingsen, S.P., Gough, R., Hunstead, R.W., Jones, D.L., McCulloch, P.M., Migenes, V., Quick, J., Sinclair, M.W., and Smits, D., “Relativistic Motion in a Nearby Bright X-Ray Source”, Nature, 374, 141–143, (1995). [External LinkDOI].
278 Tinney, C., Stathakis, R., Cannon, R., Galama, T.J., Wieringa, M.H., Frail, D.A., Kulkarni, S.R., Higdon, J.L., Wark, R.M., and Bloom, J.S., GRB 980425, IAU Circular, 6896, (Central Bureau for Astronomical Telegrams, Cambridge, 1998).
279 Toro, E.F., Riemann Solvers and Numerical Methods for Fluid Dynamics, (Springer, Berlin, 1997).
280 Tóth, G., “The ∇⋅B = 0 Constraint in Shock-Capturing Magnetohydrodynamics Codes”, J. Comput. Phys., 161, 605–652, (2000). [External LinkDOI].
281 Turatto, M., Suzuki, T., Mazzali, P.A., Benetti, S., Cappellaro, E., Danziger, I.J., Nomoto, K., Nakamura, T., Young, T.R., and Patat, F., “The Properties of Supernova 1997cy Associated with GRB 970514”, Astrophys. J. Lett., 534, L57–L61, (2000). [External LinkDOI].
282 van Leer, B.J., “Towards the ultimate conservative difference scheme. V. A second order sequel to Godunov’s method”, J. Comput. Phys., 32, 101–136, (1979). [External LinkDOI].
283 van Paradijs, J., Groot, P.J., Galama, T.J., Kouveliotou, C., Strom, R.G., Telting, J., Rutten, R.G.M., Fishman, G.J., Meegan, C.A., Pettini, M., Tanvir, N., Bloom, J.S., Pedersen, H., Nørdgaard-Nielsen, H.U., Linden-Vørnle, M., Melnick, J., van der Steene, G., Bremer, M., Naber, R., Heise, J., in ’t Zand, J.J.M., Costa, E., Feroci, M., Piro, L., Frontera, F., Zavattini, G., Nicastro, L., Palazzi, E., Bennet, L., Hanlon, L., and Parmar, A., “Transient optical emission from the error box of the gamma-ray burst of 28 February 1997”, Nature, 386, 686–689, (1997). [External LinkDOI].
284 van Paradijs, J., Kouveliotou, C., and Wijers, R.A.M.J., “Gamma-Ray Burst Afterglows”, Annu. Rev. Astron. Astrophys., 38, 379–425, (2000).
285 van Putten, M.H.P.M., “Maxwell’s equations in divergence form for general media with applications to MHD”, Commun. Math. Phys., 141, 63–77, (1991).
286 van Putten, M.H.P.M., MHD in Divergence Form: A Computational Method for Astrophysical Flow, Ph.D. Thesis, (California Institute of Technology, Pasadena, 1992).
287 van Putten, M.H.P.M., “A Numerical Implementation of MHD in Divergence Form”, J. Comput. Phys., 105, 339–353, (1993). [External LinkDOI].
288 van Putten, M.H.P.M., “A Two-Dimensional Relativistic (Γ = 3.25) Jet Simulation”, Astrophys. J., 408, L21–L24, (1993). [External LinkDOI].
289 van Putten, M.H.P.M., “A 2-Dimensional Blast Wave in Relativistic Magnetohydrodynamics”, Int. J. Bifurcat. Chaos, 4, 57–69, (1994). [External LinkDOI].
290 van Putten, M.H.P.M., “A two-dimensional numerical implementation of magnetohydrodynamics in divergence form”, SIAM J. Numer. Anal., 32, 1504–1518, (1995). [External LinkDOI].
291 van Putten, M.H.P.M., “Knots in Simulations of Magnetized Relativistic Jets”, Astrophys. J., 467, L57–L60, (1996). [External LinkDOI].
292 van Putten, M.H.P.M., “Uniqueness in MHD in divergence form: Right nullvectors and well-posedness”, J. Math. Phys., 43, 6195–6208, (1998). [External Linkastro-ph/9804139].
293 von Neumann, J., and Richtmyer, R.D., “A method for the numerical calculation of hydrodynamic shocks”, J. Appl. Phys., 21, 232–247, (1950). [External LinkDOI].
294 Walker, R.C., Benson, J.M., Unwin, S.C., Lystrup, M.B., Hunter, T.R., Pilbratt, G., and Hardee, P.E., “The Structure and Motions of the 3C 120 Radio Jet on Scales of 0.6 to 300 parsecs”, Astrophys. J., 556, 756–772, (2001). [External LinkDOI].
295 Wen, L., Panaitescu, A., and Laguna, P., “A shock-patching code for ultrarelativistic fluid flows”, Astrophys. J., 486, 919–927, (1997). [External LinkDOI].
296 Wilson, J.R., “A Numerical Method for Relativistic Hydrodynamics”, in Smarr, L.L., ed., Sources of Gravitational Radiation, Proceedings of the Battelle Seattle Workshop, July 24 – August 4, 1978, pp. 423–445, (Cambridge University Press, Cambridge; New York, 1979).
297 Wilson, J.R., and Mathews, G.J., “Relativistic hydrodynamics”, in Evans, C.R., Finn, L.S., and Hobill, D.W., eds., Frontiers in Numerical Relativity, Proceedings of the International Workshop on Numerical Relativity, University of Illinois at Urbana-Champaign, USA, 9 – 13 May 1988, pp. 306–314, (Cambridge University Press, Cambridge; New York, 1989).
298 Wilson, J.R., and Mathews, G.J., Relativistic numerical hydrodynamics, (Cambridge University Press, Cambridge, England, 2003). [External LinkGoogle Books].
299 Winicour, J., “Characteristic Evolution and Matching”, Living Rev. Relativity, 4, lrr-2001-3, (2001). URL (cited on 15 December 2003):
300 Woodward, P.R., and Colella, P., “The numerical simulation of two-dimensional fluid flow with strong shocks”, J. Comput. Phys., 54, 115–173, (1984). [External LinkDOI].
301 Woosley, S.E., “Gamma-ray bursts from stellar mass accretion disks around black holes”, Astrophys. J., 405, 273–277, (1993). [External LinkDOI], [External LinkADS].
302 Woosley, S.E., Eastman, R.G., and Schmidt, B.P., “Gamma-Ray Bursts and Type Ic Supernova SN 1998bw”, Astrophys. J., 516, 788–796, (1999). [External LinkDOI].
303 Yang, J.Y., Chen, M.H., Tsai, I.-N., and Chang, J.W., “A Kinetic Beam Scheme for Relativistic Gas Dynamics”, J. Comput. Phys., 136, 19–40, (1997). [External LinkDOI].
304 Yang, J.Y., and Hsu, C.A., “High-resolution, Non-oscillatory Schemes for Unsteady Compressible Flows”, AIAA J., 30, 1570–1575, (1992). [External LinkDOI].
305 Yang, J.Y., Huang, J.C., and Tsuei, L., “Numerical solutions of the nonlinear model Boltzmann equations”, Proc. R. Soc. London, Ser. A, 448, 55–80, (1995).
306 Yee, H.C., “Construction of explicit and implicit symmetric TVD schemes and their applications”, J. Comput. Phys., 68, 151–179, (1987). [External LinkDOI].
307 Yee, H.C., “A class of high-resolution explicit and implicit shock-capturing methods”, in Computational Fluid Dynamics, VKI Lecture Series, vol. 04, (von Karman Institute for Fluid Dynamics, Rhode-Saint-Genèse, 1989).
308 Zhang, W., Woosley, S.E., and MacFadyen, A.I., “Relativistic jets in collapsars”, Astrophys. J. Lett., 586, 356–371, (2003). [External LinkDOI], [External Linkastro-ph/0207436].