Collimated electron bunches from relativistic laser- plasma interaction at short scale length artificial pre-plasma Текст научной статьи по специальности «Физика»

Complex Systems of Charged Particles and their Interactions with Electromagnetic Radiation 2019

COLLIMATED ELECTRON BUNCHES FROM RELATIVISTIC LASERPLASMA INTERACTION AT SHORT SCALE LENGTH ARTIFICIAL

PRE-PLASMA

I.Tsymbalov12,D.Gorlova12, S.Shulyapov1, V.Prokudin1, A.Zavorotny1, K.Ivanov13, R.Volkov1,

V.Bychenkov3, V.Nedorezov2, A.Savel'ev1,3

1Physics Faculty and International Laser Center ofM.V. Lomonosov Moscow State University,

Moscow, Russia

2

Institute for Nuclear Research of Russian Academy of Sciences, Moscow, Russia 3P.N. Lebedev Physical Institute of Russian Academy of Sciences, Moscow, Russia

e-mail: abst@physics.msu.ru

We demonstrated efficient electron acceleration in the plasma channel with injection through

the breaking of plasma waves generated by parametric instabilities. It was shown experimentally that

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in the case of optimal preplasma parameters femtosecond laser pulse with an intensity of 5*10 W/cm2 and an energy of 50 mJ generates a collimated electron bunch having divergence of 50 mrad, exponential spectrum with the slope of ~2 MeV and charge of tens of pC. The charge was confirmed measuring neutron yield from Be(g,n) photonuclear reaction with threshold of 1.7 MeV.

This bunch was produced using the specific plasma profile containing arbitrary sharp gradient

at the vicinity of 0.1-0.5 critical density and a long tail of teneous preplasma. We successfully formed

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such a gradient by an additional nanosecond laser pulse with intensity of 5*10 W/cm . Its intensity must be enough for the plasma gradient steepening down to L ~ 0.5A by the ponderomotive force. This steepening happens near the critical density and provides for the efficient reflection of the subsequent femtosecond laser pulse of relativistic intensity. This reflected pulse creates plasma channel that serves for the DLA of electrons. Finally, well collimated bunch of high energy electrons emerges with mean electron energy well above the ponderomotive energy of the femtosecond pulse. Additional calculations showed that L-0.5X is the optimal scale length for the considered mechanism of electron acceleration.

Simulations of a test electron's motion in the complex electromagnetic field consisting of the laser pulse and static azimuthal electric and magnetic fields showed that an electron acquires maximum energy at the channel exit if its initial energy amounts to several hundred keV and it is injected at the instant of the maximal field of the laser pulse. Simple estimates showed that plasma waves of the hybrid SRS-TPD instability are capable of injecting electrons with required energies in the channel. This instability generates two groups of waves: one moves along the plasma surface and the other - approximately in the perpendicular direction toward lower densities. Analysis of electron's trajectories obtained from the PIC-modeling showed that the first group of waves accelerates electrons, while the field of the second group pushes electrons into the plasma channel. These waves were evidenced experimentally and numerically from the scattered 3/2w0 harmonic.