Add to ORKGThe possibility of autoresonance in a slow electromagnetic wave propagating along the straight lines of the external magnetic field is discussed. It turns out that the autoresonant regime of the motion in such a wave is possible if some rather restrictive relations between the electric drift velocity and the phase velocity of the wave take place. It also depends on the polarization of the wave. The general case of the elliptical polarization is considered. The optical regime corresponds to the wave with linear polarization in the direction of the constant electric field. For this case our calculations show that energy of the particle can unlimitedly increase or decrease. The rate of acceleration can be even larger than in the case of 'vacuu...
In this paper, the efficiency of electron acceleration by a short, powerful laser pulse propagating ...
Salamin YI, Faisal F, Keitel CH. Exact analysis of ultrahigh laser-induced acceleration of electrons...
We revisit the exact microscopic equations (in differential, and equivalent integral form) ruling a ...
The possibility of autoresonance in a slow electromagnetic wave propagating along the straight lines...
We consider the autoresonant motion of a charged particle in the field of a transverse electromagnet...
Abstract. The motion of a charged particle driven by an electromagnetic pulse of elliptical polariza...
An autoresonance electron acceleration phenomenon in the combined steady-state inhomogeneous magneti...
The electron motion at cyclotron resonance in the presence of a homogeneous time dependent magnetic ...
We propose a mechanism for electron acceleration in which circularly polarized electromagnetic waves...
The basic physical processes in laser-matter interaction, up to $10^{17}~{\rm W/cm}^2$ (for a neodym...
We revisit the exact microscopic equations (in differential, and equivalent integral form) ruling a ...
The axial evolution ofthe electromagnetic fields is solved self-consistently with the nonlinear dyna...
Using the Bogolyubov method, the solution of equations of electron motion in a combined mirror-Type ...
In the present work, we study particle motion in high-intensities electromagnetic fields plasma. Sup...
The phenomenon of trapping of weakly relativistic charged particles (with kinetic energies on the or...
In this paper, the efficiency of electron acceleration by a short, powerful laser pulse propagating ...
Salamin YI, Faisal F, Keitel CH. Exact analysis of ultrahigh laser-induced acceleration of electrons...
We revisit the exact microscopic equations (in differential, and equivalent integral form) ruling a ...
The possibility of autoresonance in a slow electromagnetic wave propagating along the straight lines...
We consider the autoresonant motion of a charged particle in the field of a transverse electromagnet...
Abstract. The motion of a charged particle driven by an electromagnetic pulse of elliptical polariza...
An autoresonance electron acceleration phenomenon in the combined steady-state inhomogeneous magneti...
The electron motion at cyclotron resonance in the presence of a homogeneous time dependent magnetic ...
We propose a mechanism for electron acceleration in which circularly polarized electromagnetic waves...
The basic physical processes in laser-matter interaction, up to $10^{17}~{\rm W/cm}^2$ (for a neodym...
We revisit the exact microscopic equations (in differential, and equivalent integral form) ruling a ...
The axial evolution ofthe electromagnetic fields is solved self-consistently with the nonlinear dyna...
Using the Bogolyubov method, the solution of equations of electron motion in a combined mirror-Type ...
In the present work, we study particle motion in high-intensities electromagnetic fields plasma. Sup...
The phenomenon of trapping of weakly relativistic charged particles (with kinetic energies on the or...
In this paper, the efficiency of electron acceleration by a short, powerful laser pulse propagating ...
Salamin YI, Faisal F, Keitel CH. Exact analysis of ultrahigh laser-induced acceleration of electrons...
We revisit the exact microscopic equations (in differential, and equivalent integral form) ruling a ...