The electron magnetohydrodynamic (EMHD) model represents an incompressible electron fluid flow against a static neutralizing background ion species. In contrast to hydrodynamic fluid models the EMHD model contains intrinsic length (the electron skin depth) and time scale (the whistler period). The paper discusses the role of skin depth and the existence of whistler waves on a prominent fluid instability, namely, the velocity shear driven Kelvin-Helmholtz instability in the context of two-dimensional EMHD. Numerical simulations are also carried out to understand the role played by the whistler waves in the nonlinear saturated regime of the instability
The nonlinear evolution of the electron temperature gradient (ETG) driven mode can be described with...
We study the stability of shear flows in a fully ionized plasma. Kelvin-Helmholtz is a well-known ma...
Two-dimensional (2D) imaging of electron temperature perturbations provides a powerful constraint fo...
We investigate the linear stability of a sheared velocity and magnetic equilibrium against "hig...
The paper discusses the free energy source for the flow shear driven instability in the context of e...
A detailed numerical simulation studying certain aspects of turbulence in the electron magnetohydrod...
This report is concerned with the influence of the Hall term on the nonlinear evolution of the Rayle...
The paper presents a complete three-dimensional linearized perturbation analysis for a sheared elect...
The influence of inertia on the spontaneous amplification of large-scale perturbations by electron m...
A detailed numerical simulation to understand the turbulent state of the decaying two-dimensional el...
The stability of current channels to fast electron magnetohydrodynamic modes is a topic of great int...
The nonlinear physics of electron magnetohydrodynamics (EMHD) in plasmas. Time-varying wave magnetic...
The Kelvin-Helmholtz (KH) instability of a shear layer with an initially uniform magnetic field in t...
A modified EMHD model is derived that includes the effects of density perturbations and inhomogeneit...
Theoretical studies of mean field electrodynamics for diffusive processes in the electron magnetohyd...
The nonlinear evolution of the electron temperature gradient (ETG) driven mode can be described with...
We study the stability of shear flows in a fully ionized plasma. Kelvin-Helmholtz is a well-known ma...
Two-dimensional (2D) imaging of electron temperature perturbations provides a powerful constraint fo...
We investigate the linear stability of a sheared velocity and magnetic equilibrium against "hig...
The paper discusses the free energy source for the flow shear driven instability in the context of e...
A detailed numerical simulation studying certain aspects of turbulence in the electron magnetohydrod...
This report is concerned with the influence of the Hall term on the nonlinear evolution of the Rayle...
The paper presents a complete three-dimensional linearized perturbation analysis for a sheared elect...
The influence of inertia on the spontaneous amplification of large-scale perturbations by electron m...
A detailed numerical simulation to understand the turbulent state of the decaying two-dimensional el...
The stability of current channels to fast electron magnetohydrodynamic modes is a topic of great int...
The nonlinear physics of electron magnetohydrodynamics (EMHD) in plasmas. Time-varying wave magnetic...
The Kelvin-Helmholtz (KH) instability of a shear layer with an initially uniform magnetic field in t...
A modified EMHD model is derived that includes the effects of density perturbations and inhomogeneit...
Theoretical studies of mean field electrodynamics for diffusive processes in the electron magnetohyd...
The nonlinear evolution of the electron temperature gradient (ETG) driven mode can be described with...
We study the stability of shear flows in a fully ionized plasma. Kelvin-Helmholtz is a well-known ma...
Two-dimensional (2D) imaging of electron temperature perturbations provides a powerful constraint fo...