Effects of nanosecond-scale prepulse on generation of high-energy protons in target normal sheath acceleration

Wang, W. P.; Shen, Baifei; Zhang, H.; Xu, Yi; Li, Y. Y.; Lu, Xiaomin; Wang, C.; Liu, Y. Q.; Lu, J.; Shi, Yin; Leng, Yuxin; Liang, Xiaoyan; Li, R. X.; Wang, N. Y.; Xu, Zhizhan

doi:10.1063/1.4809522

Cited by 25 publications

(14 citation statements)

References 20 publications

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“…[31][32][33][34][35][36][37][38][39] We expect that using the maximum sheath field to accelerate the center of the proton beam is the optimum condition for the cascaded TNSA scheme. In this case, the incident proton beam is largely accelerated and the beam spectrum is simultaneously improved.…”

Section: Simulations and Discussionmentioning

confidence: 99%

Cascaded target normal sheath acceleration

et al. 2013

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A cascaded target normal sheath acceleration (TNSA) scheme is proposed to simultaneously increase energy and improve energy spread of a laser-produced mono-energetic proton beam. An optimum condition that uses the maximum sheath field to accelerate the center of the proton beam is theoretically found and verified by two-dimensional particle-in-cell simulations. An initial 10 MeV proton beam is accelerated to 21 MeV with energy spread decreased from 5% to 2% under the optimum condition during the process of the cascaded TNSA. The scheme opens a way to scale proton energy lineally with laser energy. V C 2013 AIP Publishing LLC.

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Section: Simulations and Discussionmentioning

confidence: 99%

Cascaded target normal sheath acceleration

et al. 2013

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“…In a real situation, the counter-propagating laser can be produced automatically during the propagation of an intense laser pulse in the plasma through processes such as stimulated Raman backscattering or reflected laser fields from high density regions. However, recently fast electron generation due to relativistic intensity laser-matter interaction influenced by preformed plasma has been addressed in a number of experimental and theoretical studies [21][22][23][24][25][26][27][28], suggesting that the presence of pre-plasma can significantly affect fast electron distributions. The new foundings in experimental and theoretical studies, addressing the influences of pre-plasmas, seem beyond the interpretations of stochastic heating and acceleration models.…”

Section: Introductionmentioning

confidence: 99%

Identifying the source of super-high energetic electrons in the presence of pre-plasma in laser–matter interaction at relativistic intensities

Krasheninnikov

Luan

et al. 2016

Nucl. Fusion

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The generation of super-high energetic electrons influenced by pre-plasma at relativistic intensity laser-matter interaction is studied in a one-dimensional slab approximation with particle-in-cell simulations. Different pre-plasma scale-lengths of 1 µm, 5 µm, 10 µm and 15 µm are considered, showing an increase in both particle number and cut-off kinetic energy of electrons with the increase of pre-plasma scale-length, and the cut-off kinetic energy greatly exceeding the corresponding laser ponderomotive energy. A two-stage electron acceleration model is proposed to explain the underlying physics. The first stage is attributed to the synergetic acceleration by longitudinal electric field and laser pulse, with its efficiency depending on the pre-plasma scale-length. These electrons preaccelerated in the first stage could build up an intense electrostatic potential barrier with its maximal value several times as large of the initial electron kinetic energy. Part of energetic electrons could be further accelerated by the reflection off the electrostatic potential barrier, with their finial kinetic energies significantly higher than the values pre-accelerated in the first stage.

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“…In fact, the effect of a laser prepulse is always critical for a thin foil and it may alter the conditions [see Equations (3) and (4)]. A density gradient at the front or back side of the foil produced by the prepulse must be considered if the laser contrast is not ultra-high [9,10] ; such a condition is not considered in this work.…”

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confidence: 99%

“…These events jeopardize the relativistic interaction of the ultra-thin target. Thus, high-contrast [9][10][11][12][13][14][15][16][17][18][19][20] and short-duration laser pulses [21,22] are needed. Plasma mirrors may be a feasible method by which to solve these problems.…”

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Ion motion effects on the generation of short-cycle relativistic laser pulses during radiation pressure acceleration

Wang¹,

Zhang²,

Wang³

et al. 2014

High Pow Laser Sci Eng

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The effects of ion motion on the generation of short-cycle relativistic laser pulses during radiation pressure acceleration are investigated by analytical modeling and particle-in-cell simulations. Studies show that the rear part of the transmitted pulse modulated by ion motion is sharper compared with the case of the electron shutter only. In this study, the ions further modulate the short-cycle pulses transmitted. A 3.9 fs laser pulse with an intensity of 1.33 × 10 21 W cm −2 is generated by properly controlling the motions of the electron and ion in the simulations. The short-cycle laser pulse source proposed can be applied in the generation of single attosecond pulses and electron acceleration in a small bubble regime.

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Effects of nanosecond-scale prepulse on generation of high-energy protons in target normal sheath acceleration

Cited by 25 publications

References 20 publications

Cascaded target normal sheath acceleration

Cascaded target normal sheath acceleration

Identifying the source of super-high energetic electrons in the presence of pre-plasma in laser–matter interaction at relativistic intensities

Ion motion effects on the generation of short-cycle relativistic laser pulses during radiation pressure acceleration

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