螺旋光束中直接激光驱动的电子加速和能量增益

IF 1.1 4区物理与天体物理 Q4 PHYSICS, APPLIED Laser and Particle Beams Pub Date : 2021-03-26 DOI:10.1155/2021/6645668

E. Moln'ar, D. Stutman

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引用次数: 2

摘要

直接激光驱动电子加速的近轴拉盖尔-高斯模式的详细研究，对应于具有方位模式的螺旋光束lg0 mM = 1,2,3,4,5。由于基态高斯光束的质动势与螺旋光束的质动势不同0米;我们发现，在半最大值处，导致全宽处能量最大的电子的最佳束腰比后者小两倍以上，并且对应于几个波长Δ w 0 =P的激光功率为6,11,19 λ 00 = 0.1,1,10 pw。我们还发现，当方位模态m≥3时，最佳腰围应小于Δ w 0 19 λ0 .利用这些最优值，我们观察到电子在螺旋光束中的平均动能增益比基本高斯光束大一个数量级。这种平均能量增益随着方位角指数m的增加而增加，导致在激光传播方向上有几个100 MeV能量的准直电子。

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Direct Laser-Driven Electron Acceleration and Energy Gain in Helical Beams

A detailed study of direct laser-driven electron acceleration in paraxial Laguerre–Gaussian modes corresponding to helical beams

{LG}_{0 m}

with azimuthal modes

m = \{1,2,3,4,5\}

is presented. Due to the difference between the ponderomotive force of the fundamental Gaussian beam

{LG}_{00}

and helical beams

{LG}_{0 m}

, we found that the optimal beam waist leading to the most energetic electrons at full width at half maximum is more than twice smaller for the latter and corresponds to a few wavelengths

Δ w_{0} = \{6,11,19\} λ_{0}

for laser powers of

P_{0} = \{0.1, 1,10\}

PW. We also found that, for azimuthal modes

m \geq 3

, the optimal waist should be smaller than

Δ w_{0} < 19 λ_{0}

. Using these optimal values, we have observed that the average kinetic energy gain of electrons is about an order of magnitude larger in helical beams compared to the fundamental Gaussian beam. This average energy gain increases with the azimuthal index

m

leading to collimated electrons of a few 100 MeV energy in the direction of the laser propagation.

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来源期刊

Laser and Particle Beams PHYSICS, APPLIED-

CiteScore

1.90

自引率

11.10%

发文量

审稿时长

1 months

期刊介绍： Laser and Particle Beams is an international journal which deals with basic physics issues of intense laser and particle beams, and the interaction of these beams with matter. Research on pulse power technology associated with beam generation is also of strong interest. Subjects covered include the physics of high energy densities; non-LTE phenomena; hot dense matter and related atomic, plasma and hydrodynamic physics and astrophysics; intense sources of coherent radiation; high current particle accelerators; beam-wave interaction; and pulsed power technology.