Evolution of slow electrostatic shock into a plasma shock mediated by electrostatic turbulence

The collision of two plasma clouds at a speed that exceeds the ion acoustic speed can result in the formation of shocks. This phenomenon is observed not only in astrophysical scenarios, such as the propagation of supernova remnant (SNR) blast shells into the interstellar medium, but also in laboratory-based laser-plasma experiments. These experiments and supporting simulations are thus seen as an attractive platform for small-scale reproduction and study of astrophysical shocks in the laboratory. We model two plasma clouds, which consist of electrons and ions, with a 2D particle-in-cell simulation. The ion temperatures of both clouds differ by a factor of ten. Both clouds collide at a speed that is realistic for laboratory studies and for SNR shocks in their late evolution phase, like that of RCW86. A magnetic field, which is orthogonal to the simulation plane, has a strength that is comparable to that of SNR shocks. A forward shock forms between the overlap layer of both plasma clouds and the cloud with cooler ions. A large-amplitude ion acoustic wave is observed between the overlap layer and the cloud with hotter ions. It does not steepen into a reverse shock because its speed is below the ion acoustic speed. A gradient of the magnetic field amplitude builds up close to the forward shock as it compresses the magnetic field. This gradient gives rise to an electron drift that is fast enough to trigger an instability. Electrostatic ion acoustic wave turbulence develops ahead of the shock, widens its transition layer, and thermalizes the ions, but the forward shock remains intact.

[1]  A. Stockem,et al.  Exploring the nature of collisionless shocks under laboratory conditions , 2014, Scientific Reports.

[2]  P. Chang,et al.  Filamentation instability of counterstreaming laser-driven plasmas. , 2013, Physical review letters.

[3]  M. Pohl,et al.  Modification of the formation of high-Mach number electrostatic shock-like structures by the ion acoustic instability , 2013, 1310.1740.

[4]  E. Ramirez-Ruiz,et al.  A CHANDRA VIEW OF NON-THERMAL EMISSION IN THE NORTHWESTERN REGION OF SUPERNOVA REMNANT RCW 86: PARTICLE ACCELERATION AND MAGNETIC FIELDS , 2013, 1309.2936.

[5]  R. Narayan,et al.  The formation of a collisionless shock , 2013 .

[6]  A. Giesecke,et al.  Time-resolved characterization of the formation of a collisionless shock. , 2013, Physical review letters.

[7]  M. Pohl,et al.  Parametric study of non-relativistic electrostatic shocks and the structure of their transition layer , 2013, 1304.6523.

[8]  L. Silva,et al.  Relativistic collisionless shocks formation in pair plasmas , 2013, Journal of Plasma Physics.

[9]  L. Gremillet,et al.  Collisionless shock formation, spontaneous electromagnetic fluctuations and streaming instabilities , 2013, 1303.4095.

[10]  Marco Borghesi,et al.  Ion acceleration by superintense laser-plasma interaction , 2013, 1302.1775.

[11]  C. Niemann,et al.  Dynamics of exploding plasmas in a large magnetized plasma , 2013 .

[12]  R. P. Drake,et al.  Self-organized electromagnetic field structures in laser-produced counter-streaming plasmas , 2012, Nature Physics.

[13]  T. Arber,et al.  Rapid filamentation of high power lasers at the quarter critical surface , 2012 .

[14]  R. Yamazaki,et al.  Microinstabilities at perpendicular collisionless shocks: A comparison of full particle simulations with different ion to electron mass ratio , 2012, 1204.2539.

[15]  M. Borghesi,et al.  Weibel-induced filamentation during an ultrafast laser-driven plasma expansion. , 2012, Physical review letters.

[16]  Chao Gong,et al.  Collisionless shocks in laser-produced plasma generate monoenergetic high-energy proton beams , 2011, Nature Physics.

[17]  Lev M. Zelenyi,et al.  Investigation of intermittency and generalized self-similarity of turbulent boundary layers in laboratory and magnetospheric plasmas: towards a quantitative definition of plasma transport features , 2011 .

[18]  I. Kourakis,et al.  Generation of a purely electrostatic collisionless shock during the expansion of a dense plasma through a rarefied medium. , 2011, Physical review letters.

[19]  Anders Ynnerman,et al.  Two-dimensional particle-in-cell simulation of the expansion of a plasma into a rarefied medium , 2011 .

[20]  J. Vink,et al.  TEMPERATURE EQUILIBRATION BEHIND THE SHOCK FRONT: AN OPTICAL AND X-RAY STUDY OF RCW 86 , 2011, 1106.0303.

[21]  N. Woolsey,et al.  Time evolution of collisionless shock in counterstreaming laser-produced plasmas. , 2011, Physical review letters.

[22]  T. Kato,et al.  Collisionless shock generation in high-speed counterstreaming plasma flows by a high-power laser , 2010 .

[23]  Marco Borghesi,et al.  The application of laser-driven proton beams to the radiography of intense laser–hohlraum interactions , 2010 .

[24]  Hideaki Takabe,et al.  Electrostatic and electromagnetic instabilities associated with electrostatic shocks: Two-dimensional particle-in-cell simulation , 2010, 1003.1217.

[25]  A. Dangor,et al.  Generation of ultrahigh-velocity ionizing shocks with petawatt-class laser pulses. , 2009, Physical review letters.

[26]  J. Raymond Cosmic-Ray Acceleration in Supernova Remnants , 2009, Science.

[27]  S. Funk,et al.  Measuring the Cosmic-Ray Acceleration Efficiency of a Supernova Remnant , 2009, Science.

[28]  O Willi,et al.  Observation of collisionless shocks in laser-plasma experiments. , 2008, Physical review letters.

[29]  Z. Sheng,et al.  Ion acceleration by colliding electrostatic shock waves in laser-solid interaction , 2007 .

[30]  Jie Zhang,et al.  Collisionless electrostatic shock generation and ion acceleration by ultraintense laser pulses in overdense plasmas , 2007 .

[31]  S. Bale,et al.  Measurement of large parallel and perpendicular electric fields on electron spatial scales in the terrestrial bow shock. , 2007, Physical review letters.

[32]  P. Shukla,et al.  Particle-in-cell simulations of plasma slabs colliding at a mildly relativistic speed , 2006 .

[33]  D. Burgess,et al.  Transition scale at quasiperpendicular collisionless shocks: Full particle electromagnetic simulations , 2006 .

[34]  R. E. Lee,et al.  Perpendicular Shock Reformation and Ion Acceleration , 2005 .

[35]  Erik Lefebvre,et al.  Proton acceleration mechanisms in high-intensity laser interaction with thin foils , 2005 .

[36]  M. Haase,et al.  Discrete model for laser driven etching and microstructuring of metallic surfaces. , 2005, Physical review. E, Statistical, nonlinear, and soft matter physics.

[37]  G. Lapenta,et al.  Nonlinear evolution of the lower-hybrid drift instability in a current sheet. , 2004, Physical review letters.

[38]  T. Horbury,et al.  Electric field scales at quasi-perpendicular shocks , 2004 .

[39]  Michael Marti,et al.  Proton shock acceleration in laser-plasma interactions. , 2004, Physical review letters.

[40]  E. Berezhko,et al.  Confirmation of strong magnetic field amplification and nuclear cosmic ray acceleration in SN 1006 , 2003, astro-ph/0310862.

[41]  William Daughton,et al.  Electromagnetic properties of the lower-hybrid drift instability in a thin current sheet , 2003 .

[42]  Marco Borghesi,et al.  Electric field detection in laser-plasma interaction experiments via the proton imaging technique , 2001 .

[43]  K. Ferrière The interstellar environment of our galaxy , 2001, astro-ph/0106359.

[44]  R. Smith,et al.  Balmer-dominated Spectra of Nonradiative Shocks in the Cygnus Loop, RCW 86, and Tycho Supernova Remnants , 2000, astro-ph/0010496.

[45]  Gu,et al.  Forward ion acceleration in thin films driven by a high-intensity laser , 2000, Physical review letters.

[46]  Hideaki Takabe,et al.  Modeling astrophysical phenomena in the laboratory with intense lasers , 1999 .

[47]  R. Petre,et al.  Evidence for shock acceleration of high-energy electrons in the supernova remnant SN1006 , 1995, Nature.

[48]  I. Mirabel,et al.  A double-sided radio jet from the compact Galactic Centre annihilator 1E1740.7–2942 , 1992, Nature.

[49]  N. Omidi,et al.  Two-dimensional simulations of the ion/ion acoustic instability and electrostatic shocks , 1991 .

[50]  H. Schamel,et al.  Plasma expansion into vacuum — A hydrodynamic approach , 1987 .

[51]  R. Kristal,et al.  Fast ions and hot electrons in the laser–plasma interaction , 1986 .

[52]  H. Schamel,et al.  Electron holes, ion holes and double layers: Electrostatic phase space structures in theory and experiment , 1986 .

[53]  J. Brackbill,et al.  Nonlinear evolution of the lower‐hybrid drift instability , 1984 .

[54]  J. Dawson Particle simulation of plasmas , 1983 .

[55]  N. Hershkowitz Double layers and electrostatic shocks , 1981 .

[56]  J. Allen,et al.  The expansion of a plasma into a vacuum , 1975, Journal of Plasma Physics.

[57]  A. Barnes Collisionless Damping of Hydromagnetic Waves , 1966 .

[58]  E. A. Jackson DRIFT INSTABILITIES IN A MAXWELLIAN PLASMA , 1960 .

[59]  P. Shukla,et al.  Formation and dynamics of coherent structures involving phase-space vortices in plasmas , 2006 .

[60]  Thomas A. Weaver,et al.  The Physics of Supernova Explosions , 1986 .

[61]  J. Fu,et al.  Electron Cyclotron Drift Instability and Turbulence , 1972 .

[62]  J. Freidberg,et al.  THEORY OF LAMINAR COLLISIONLESS SHOCKS. , 1971 .

[63]  C. Shonk,et al.  NUMERICAL SIMULATION OF ELECTROSTATIC COUNTERSTREAMING INSTABILITIES IN ION BEAMS. , 1970 .

[64]  C. Shonk,et al.  FORMATION AND STRUCTURE OF ELECTROSTATIC COLLISIONLESS SHOCKS. , 1970 .