Interplay between intermittency and dissipation in collisionless plasma turbulence

We study the damping of collisionless Alfvénic turbulence in a strongly magnetised plasma by two mechanisms: stochastic heating (whose efficiency depends on the local turbulence amplitude $\unicode[STIX]{x1D6FF}z_{\unicode[STIX]{x1D706}}$ ) and linear Landau damping (whose efficiency is independent of $\unicode[STIX]{x1D6FF}z_{\unicode[STIX]{x1D706}}$ ), describing in detail how they affect and are affected by intermittency. The overall efficiency of linear Landau damping is not affected by intermittency in critically balanced turbulence, while stochastic heating is much more efficient in the presence of intermittent turbulence. Moreover, stochastic heating leads to a drop in the scale-dependent kurtosis over a narrow range of scales around the ion gyroscale.

Download Full-text

Fluidization of collisionless plasma turbulence

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1813913116 ◽

2019 ◽

Vol 116 (4) ◽

pp. 1185-1194 ◽

Cited By ~ 13

Author(s):

Romain Meyrand ◽

Anjor Kanekar ◽

William Dorland ◽

Alexander A. Schekochihin

Keyword(s):

Solar Wind ◽

Power Law ◽

Collisionless Plasma ◽

Plasma Turbulence ◽

Magnetized Plasma ◽

Landau Damping ◽

Astrophysical Plasmas ◽

Phase Mixing ◽

Fluid Turbulence ◽

Collisionless Plasmas

In a collisionless, magnetized plasma, particles may stream freely along magnetic field lines, leading to “phase mixing” of their distribution function and consequently, to smoothing out of any “compressive” fluctuations (of density, pressure, etc.). This rapid mixing underlies Landau damping of these fluctuations in a quiescent plasma—one of the most fundamental physical phenomena that makes plasma different from a conventional fluid. Nevertheless, broad power law spectra of compressive fluctuations are observed in turbulent astrophysical plasmas (most vividly, in the solar wind) under conditions conducive to strong Landau damping. Elsewhere in nature, such spectra are normally associated with fluid turbulence, where energy cannot be dissipated in the inertial-scale range and is, therefore, cascaded from large scales to small. By direct numerical simulations and theoretical arguments, it is shown here that turbulence of compressive fluctuations in collisionless plasmas strongly resembles one in a collisional fluid and does have broad power law spectra. This “fluidization” of collisionless plasmas occurs, because phase mixing is strongly suppressed on average by “stochastic echoes,” arising due to nonlinear advection of the particle distribution by turbulent motions. Other than resolving the long-standing puzzle of observed compressive fluctuations in the solar wind, our results suggest a conceptual shift for understanding kinetic plasma turbulence generally: rather than being a system where Landau damping plays the role of dissipation, a collisionless plasma is effectively dissipationless, except at very small scales. The universality of “fluid” turbulence physics is thus reaffirmed even for a kinetic, collisionless system.

Download Full-text

Lower-hybrid-heating data on the Wega experiment revisited, using ion-stochastic-heating and electron-Landau-damping theories

Nuclear Fusion ◽

10.1088/0029-5515/21/9/001 ◽

1981 ◽

Vol 21 (9) ◽

pp. 1047-1065 ◽

Cited By ~ 19

Author(s):

C. Gormezano ◽

W. Hess ◽

G. Ichtchenko ◽

R. Magne ◽

T.K. Nguyen ◽

...

Keyword(s):

Landau Damping ◽

Lower Hybrid ◽

Hybrid Heating ◽

Stochastic Heating

Download Full-text

Evidence for electron Landau damping in space plasma turbulence

Nature Communications ◽

10.1038/s41467-019-08435-3 ◽

2019 ◽

Vol 10 (1) ◽

Cited By ~ 37

Author(s):

C. H. K. Chen ◽

K. G. Klein ◽

G. G. Howes

Keyword(s):

Space Plasma ◽

Plasma Turbulence ◽

Landau Damping

Download Full-text

Stimulated Brillouin backscattering of a ring-rippled laser beam in collisionless plasma

Laser and Particle Beams ◽

10.1017/s0263034615000555 ◽

2015 ◽

Vol 33 (3) ◽

pp. 499-509 ◽

Cited By ~ 5

Author(s):

Gunjan Purohit ◽

Priyanka Rawat

Keyword(s):

Laser Beam ◽

Narrow Range ◽

Brillouin Scattering ◽

Collisionless Plasma ◽

Plasma Parameters ◽

Ion Acoustic Wave ◽

Coupled Equations ◽

Ion Acoustic ◽

Paraxial Ray ◽

Stimulated Brillouin

AbstractThe effect of the propagation of a ring-rippled laser beam in the presence of relativistic and ponderomotive non-linearities on the excitation of ion-acoustic wave (IAW) and resulting stimulated Brillouin backscattering in collisionless plasma at relativistic powers is studied. To understand the nature of propagation of the ring ripple-like instability, a paraxial-ray approach has been invoked in which all the relevant parameters correspond to a narrow range around the irradiance maximum of the ring ripple. Modified coupled equations for growth of ring ripple in the plasma, generations of IAW and back-stimulated Brillouin scattering (SBS) are derived from fluid equations. These coupled equations are solved analytically and numerically to study the intensity of ring-rippled laser beam and excited IAW as well as back reflectivity of SBS in the plasma for various established laser and plasma parameters. It is found that the back reflectivity of SBS is enhanced due to the strong coupling between ring-rippled laser beam and the excited IAW. The results also show that the back reflectivity of SBS reduce for higher intensity of the laser beam.

Download Full-text

Free energy sources in kinetic scale current sheets formed in collisionless plasma turbulence

10.5194/egusphere-egu2020-21518 ◽

2020 ◽

Author(s):

Neeraj Jain ◽

Joerg Buechner

Keyword(s):

Solar Wind ◽

Free Energy ◽

Collisionless Plasma ◽

Plasma Turbulence ◽

Energy Sources ◽

Ion Temperature ◽

Temperature Anisotropy ◽

Current Sheets ◽

Adiabatic Cooling ◽

Collisionless Dissipation

Spacecraft observations show the radial dependence of the solar wind temperature to be slower than what is expected from the adiabatic cooling of the solar wind expanding radially outwards from the sun. The most viable process considered to explain the observed slower-than-adiabatic cooling is the heating of the solar wind plasma by dissipation of the turbulent fluctuations. In solar wind which is &#160;a collisionless plasma in turbulent state, macroscopic energy is cascaded down to kinetic scales where kinetic plasma processes can finally dissipate the energy into heat. The kinetic scale plasma processes responsible &#160;for the dissipation of energy are, however, not well understood. A number of observational and simulation studies have shown that the heating is concentrated in and around current sheets self-consistently formed at kinetic scales. The current sheets contain free energy sources for the growth of plasma instabilities which can serve as the mechanism of the collisionless dissipation. A detailed information on the free energy sources contained in these current sheets of plasma turbulence is lacking but essential to understand the role of &#160;plasma instabilities in collisionless dissipation.We carry out 2-D hybrid simulations of kinetic plasma turbulence to study in detail free energy sources available in the current sheets formed in the turbulence. We focus on three free energy sources, namely, plasma density gradient, velocity gradients for both ions and electrons and ion temperature anisotropy. Our simulations show formation of current sheets in which electric current parallel to the externally applied magnetic field flows in a thickness of the order of an ion inertial length. Inside a current sheet, electron flow velocity dominates ion flow velocity in the parallel direction resulting in a larger cross-gradient of the former. The perpendicular electron velocity inside a current sheet also has variations sharper than the corresponding ion velocity. Cross gradients in plasma density are weak (under 10 % variation inside current sheets). Ion temperature is anisotropic in current sheets. Thus the current in the sheets is primarily due to electron shear flow. A theoretical model to explain the difference between electron and ion velocities in current sheets is developed. Spacecraft observations of electron shear flow in space plasma turbulence will be pointed out. &#160;&#160;These results suggest that the current sheets formed in kinetic plasma turbulence are close to the force free equilibrium rather than the often assumed Harris equilibrium. &#160;This demands investigations of the linear stability properties and nonlinear evolution of force free current sheets with temperature anisotropy. Such studies can provide effective dissipation coefficients to be included in macroscopic model of the solar wind evolution. &#160;&#160;

Download Full-text