Filamentation Instability of Counterstreaming Laser-Driven Plasmas

Fox, W.; Fiksel, G.; Bhattacharjee, A.; Chang, Po-Yu; Germaschewski, K.; Hu, S. X.; Nilson, P. M.

doi:10.1103/physrevlett.111.225002

Cited by 187 publications

(191 citation statements)

References 33 publications

(42 reference statements)

Supporting

Mentioning

181

Contrasting

Unclassified

Order By: Relevance

“…Recent laser-driven shock experiments showed the appearance of an electromagnetic field structure [22][23][24], which was attributed to the ion-filamentation instability [25] that evolves on time scales of ten thousands of the inverse electron plasma frequency, ω −1 pe . As a main outcome of this Letter, we show that these structures can already be seeded and produced on tens of ω −1 pe and remain in a quasisteady state over thousands of ω −1 pe .…”

mentioning

confidence: 99%

Electromagnetic Field Generation in the Downstream of Electrostatic Shocks Due to Electron Trapping

et al. 2014

View full text Add to dashboard Cite

A new magnetic field generation mechanism in electrostatic shocks is found, which can produce fields with magnetic energy density as high as 0.01 of the kinetic energy density of the flows on time scales ∼10 4 ω −1 pe . Electron trapping during the shock formation process creates a strong temperature anisotropy in the distribution function, giving rise to the pure Weibel instability. The generated magnetic field is well confined to the downstream region of the electrostatic shock. The shock formation process is not modified, and the features of the shock front responsible for ion acceleration, which are currently probed in laserplasma laboratory experiments, are maintained. However, such a strong magnetic field determines the particle trajectories downstream and has the potential to modify the signatures of the collisionless shock. Collisionless shocks have been studied for many decades, mainly in the context of space and astrophysics [1][2][3][4]. Recently, shock acceleration raised significant interest in the quest for a laser-based ion acceleration scheme due to an experimentally demonstrated high beam quality [5][6][7][8].Interpenetrating plasma slabs of hot electrons and cold ions are acting to set up the electrostatic fields via longitudinal plasma instabilities. The lighter electrons leaving the denser regions are held back by the electric fields, which pull the ions. Particles are trapped in the associated electrostatic potential, which steepens and eventually reaches a quasisteady-state collisionless electrostatic shock. Most of the theoretical work dates back to the 1970s [9-13] relying on the pseudo-Sagdeev potential [14] and progress has been mainly triggered by kinetic simulations [15][16][17][18].The short formation time scales and the one dimensionality of the problem make it easily accessible with theory and computer simulations. However, long time shock evolution was often one dimensional or electrostatic codes were used, and the role of electromagnetic modes was mostly neglected. More advanced multidimensional simulations have shown the importance of electromagnetic modes also in this context, due to transverse modes which are excited on the ion time scale [19,20]. We show that in the case of very high electron temperatures associated with the formation of electrostatic shocks [21], electromagnetic modes become important on electron time scales, creating strong magnetic fields in the downstream of the shock.With the increase in laser energy and intensity, the possibility to drive electrostatic shocks has become important for laboratory experiments of electrostatic shocks. Recent laser-driven shock experiments showed the appearance of an electromagnetic field structure [22][23][24], which was attributed to the ion-filamentation instability [25] that evolves on time scales of ten thousands of the inverse electron plasma frequency, ω −1 pe . As a main outcome of this Letter, we show that these structures can already be seeded and produced on tens of ω −1 pe and remain in a quasisteady state over t...

show abstract

mentioning

confidence: 99%

Electromagnetic Field Generation in the Downstream of Electrostatic Shocks Due to Electron Trapping

et al. 2014

View full text Add to dashboard Cite

show abstract

“…Recent rapid growth of laser technologies allows us to model space and astrophysical phenomena in laboratories (Drake 1999;Remington et al 1999Remington et al , 2006Takabe et al 1999). For instance, collisionless shocks have been experimentally investigated in laser-produced counterstreaming plasmas (Morita et al 2010Kuramitsu et al 2011Kuramitsu et al , 2012Kugland et al 2012;Ross et al 2012;Fox et al 2013;Yuan et al 2013;Huntington et al 2015;Park et al 2015).W efirst reported the relatively laminar density jump with optical interferometry in collisionless counterstreaming plasmas in the absence of an external magnetic field using the Shenguang II laser facility (Morita et al 2010). In order to distinguish shock from contact surface we measured the emission jump and its time evolutions with self-emission optical pyrometry (SOP) with the Gekko XII (GXII) laser facility (Kuramitsu et al 2011).…”

Section: Introductionmentioning

confidence: 99%

“…With the OMEGA and OMEGA EP laser facilities, symmetric counterstreaming plasmas can be produced (Kugland et al 2012;Ross et al 2012). In the symmetric conditions, KHI is less effective, however, filamentation instability or Weibel instability can take place where the magnetic filaments grow in the shock transition region (Fox et al 2013;Yuan et al 2013;Huntington et al 2015;Park et al 2015). Currently verifications of collisionless shock formation due to Weibel-type instability are ongoing with the world largest laser facility, the National Ignition Facility.…”

Section: Introductionmentioning

confidence: 99%

Time Evolution of Kelvin–helmholtz Vortices Associated With Collisionless Shocks in Laser-Produced Plasmas

Kuramitsu

Mizuta

Sakawa

et al. 2016

ApJ

View full text Add to dashboard Cite

We report experimental results on Kelvin-Helmholtz (KH) instability and resultant vortices in laser-produced plasmas. By irradiating a double plane target with a laser beam, asymmetric counterstreaming plasmas are created. The interaction of the plasmas with different velocities and densities results in the formation of asymmetric shocks, where the shear flow exists along the contact surface and the KH instability is excited. We observe the spatial and temporal evolution of plasmas and shocks with time-resolved diagnostics over several shots. Our results clearly show the evolution of transverse fluctuations, wavelike structures, and circular features, which are interpreted as the KH instability and resultant vortices. The relevant numerical simulations demonstrate the time evolution of KH vortices and show qualitative agreement with experimental results. Shocks, and thus the contact surfaces, are ubiquitous in the universe; our experimental results show general consequences where two plasmas interact.

show abstract

“…[24][25][26] In contrast to the aforementioned solid-density plasmas, these plasmas flow freely in-between laser ablated metal plates. 23,[27][28][29][30] This is achieved via weaker laser intensities and longer pulse durations ($10 14 W/cm 2 and $1 ns, for a recent Omega laser experiment)-although higher intensities are believed to be required for the creation of a shock. 27,28 Recently, the formation of filamentary structures indicative of ion-driven Weibel-like magnetic fields has been observed in a scaled laboratory experiment at the Omega Laser Facility.…”

Section: Introductionmentioning

confidence: 99%

“…27,28 Recently, the formation of filamentary structures indicative of ion-driven Weibel-like magnetic fields has been observed in a scaled laboratory experiment at the Omega Laser Facility. [28][29][30] Electrons moving in small-scale magnetic turbulence emit radiation that is distinct from both synchrotron and cyclotron radiation. In the context of plasma astrophysics, this radiation is known as "jitter" radiation.…”

Section: Introductionmentioning

confidence: 99%

Radiation from particles moving in small-scale magnetic fields created in solid-density laser-plasma laboratory experiments

Keenan

Medvedev

2015

Physics of Plasmas

View full text Add to dashboard Cite

Plasmas created by high-intensity lasers are often subject to the formation of kineticstreaming instabilities, such as the Weibel instability, which lead to the spontaneous generation of high-amplitude, tangled magnetic fields. These fields typically exist on small spatial scales, i.e. "sub-Larmor scales". Radiation from charged particles moving through small-scale electromagnetic (EM) turbulence has spectral characteristics distinct from both synchrotron and cyclotron radiation, and it carries valuable information on the statistical properties of the EM field structure and evolution. Consequently, this radiation from laserproduced plasmas may offer insight into the underlying electromagnetic turbulence. Here we investigate the prospects for, and demonstrate the feasibility of, such direct radiative diagnostics for mildly relativistic, solid-density laser plasmas produced in lab experiments.

show abstract

Filamentation Instability of Counterstreaming Laser-Driven Plasmas

Cited by 187 publications

References 33 publications

Electromagnetic Field Generation in the Downstream of Electrostatic Shocks Due to Electron Trapping

Electromagnetic Field Generation in the Downstream of Electrostatic Shocks Due to Electron Trapping

Time Evolution of Kelvin–helmholtz Vortices Associated With Collisionless Shocks in Laser-Produced Plasmas

Radiation from particles moving in small-scale magnetic fields created in solid-density laser-plasma laboratory experiments

Contact Info

Product

Resources

About