Propagation of short laser pulses in partially stripped plasma

LIU Jianpeng; LIU Mingping; TAO Xiangyang; LIU Sanqiu

doi:10.7510/jgjs.issn.1001-3806.2015.03.018

Volume 39 Issue 3

Mar. 2015

Article Contents

Turn off MathJax

Article Navigation > LASER TECHNOLOGY > 2015 > 39(3): 361-365

Citation:

Propagation of short laser pulses in partially stripped plasma

1.
College of Physics & Communication Electronics, Jiangxi Normal University, Nanchang 330022, China;
2.
College of Information Engineering, Nanchang University, Nanchang 330031, China;
3.
Department of Physics, Nanchang University, Nanchang 330047, China

Corresponding author: TAO Xiangyang, x.y.tao@163.com ;
Received Date: 2014-03-24
Accepted Date: 2014-04-14

Abstract

In order to study the propagation characteristics of short laser pulses in partially stripped plasma, parameters evolution equation of short laser pulses in partially ionized plasma was derived using variational method. The effect parameters of wakefield, relativistic self-focusing and intensity of partially stripped plasma were analyzed. The coupled evolution equations of the laser spot size and the pulse length were derived and the propagation of a short laser pulse in partially stripped plasma was analyzed under the effects of transverse wakefield(TWF) and longitudinal wakefield(LWF). The results show that laser pulse can be allowed to propagate in patitally stripped plasma only when a certain condition is satisfied. The evolution of the pulse length should be considered in partially stripped plasma. When laser pulse and plasma density is constant, with the increasing of ionization degree, wakefield will enhance the self-focusing of the laser pulse further. Longitudinal wakefield has more obvious effect on self-focusing of laser pulse than transverse wakefield. The results may be significant theoretically to the mechanism of ionization-induced injection and acceleration by an intense laser pulse.
- laser optics,
- partially stripped plasmas,
- wakefield,
- spot radius,
- pulse length

References

[1]	TAJIMA T, DAWSON J M. Laser electron accelerator[J].Physics Review Letters, 1979,43(4): 267-270.
[2]	NUCKOLLS J H, WOOD L, THIESSEN A R, et al. Laser compression of matter to super-high densities: thermonuclear (CTR) Applications[J].Nature, 1972,239(15):139-142.
[3]	TABAK M, HAMMER J, GLINSKY M E, et al. Ignition and high gain with ultrapowerful lasers[J].Physics Plasmas, 1994,1(5):1626-1634.
[4]	LINDL J D, Development of the indirect-drive approach to inertial confinement fusion and the target physics basis for ignition and gain[J]. Physics Plasmas, 1995,2(2):3933-4025.
[5]	ESAREY E, SPRANGLE P, KRALL J, et al. Overview of plasma-based accelerator concepts[J].IEEE Transactiong Plasma Science,1996,24(2):252-288.
[6]	HAO D Sh. A new accelerated mechanism of protons in high power laser-plasma [J]. Laser Technology, 2012, 36(4):653-656(in Chinese).
[7]	SPRANGLE P, HAFIZI B, PENANO J R, et al. Wakefield generation and GeV acceleration in tapered plasma channels[J].Physics Review, 2001,E63(5):056405.
[8]	MILCHBERG H M, DURFEE Ⅲ C G, MCILRATH T J. High-order frequency conversion in the plasma waveguide[J].Physics Review Letters,1995,75(13):2494-2497.
[9]	MAcKLIN J, KMETEC J, GORDON C. High-order harmonic generation using intense femtosecond pulses[J].Physics Review Letters,1993,70(6):766-769.
[10]	ZHOU J, PEATROSS J, MURNANE M M, et al. Enhanced high-harmonic generation using 25fs laser pulses[J].Physics Review Letters,1996,76(5):752-755.
[11]	SPRANGLE P, ESAREY E. Interaction of ultrahigh laser fields with beams and plasmas[J].Physics Fluids, 1992,B4(7):2241-2248.
[12]	HONG X R, XIE B S, ZHANG S, et al. Wakefield effects and solitary waves of an intense short laser pulse propagation in a plasma channel[J].Physics Plasmas,2011,18(10):103106.
[13]	HU Q L, XIAO G L, RUAN W, et al. One-dimensional EM solitons in ultrashort intense laser pulse-partially stripped plasmas[J].Physics Letters,2010,A374(7):965-968.
[14]	SPRANGLE P, ESAREY E, HAFIZI B. Propagation and stability of intense laser pulses in partially stripped plasmas[J].Physics Review,1997,E56(5):5894-5907.
[15]	SPRANGLE P, ESAREY E, HAFIZI B. Intense laser pulse propagation and stability in partially stripped plasmas[J].Physics Review Letters,1997,79(6):1046-1049.
[16]	MANGLES S P D, MURPHY C D, NAJMUDIN Z, et al. Monoenergetic beams of relativistic electrons from intense laser-plasma interactions[J].Nature, 2004,431(7008):535-538.
[17]	GEDDES C G R, TOTH C S, van TILBORG J, et al. Observations of longitudinal and transverse self-injections in laser-plasma wakefield accelerators[J].Nature, 2004,431(7008):538-541.
[18]	FAURE J, GLIEC Y, PUKHOV A, et al. A laser-plasma accelerator producing monoenergetic electron beams[J].Nature,2004,431(7008):541-544.
[19]	LU W, HUANG C, ZHOU M, et al. Nonlinear theory for relativistic plasma wakefields in the blowout regime[J].Physics Review Letters, 2006,96(16):165002-165005.
[20]	LEEMANS W P, NAGLER B, GONSALVES A J, et al. GeV electron beams from a centimetre-scale accelerator[J].Nature Physics, 2006,2(10):696-699.
[21]	LIU M P, ZHENG Z, LIU S Q. Effects of Relativistic and ponderomotive nonlinearities on an intense laser pulse propagation in a plasma channel[J]. Communications in Theoretical Physics,2012,58(10):569-572.
[22]	PALLAVI J, VIJAY S, AJAY K, et al. Self-focusing and compression of laser pulses in partially stripped plasma[J].Physics Plasmas, 2011,18(7):073105.

Proportional views

通讯作者: 陈斌, bchen63@163.com

1.
沈阳化工大学材料科学与工程学院沈阳 110142

Get Citation

PDF

XML

Article views(3486) PDF downloads(362) Cited by()

Proportional views

Propagation of short laser pulses in partially stripped plasma

Corresponding author: TAO Xiangyang, x.y.tao@163.com;

1. College of Physics & Communication Electronics, Jiangxi Normal University, Nanchang 330022, China;

2. College of Information Engineering, Nanchang University, Nanchang 330031, China;

3. Department of Physics, Nanchang University, Nanchang 330047, China

Received Date: 2014-03-24

Accepted Date: 2014-04-14

Available Online: 2015-05-25

Abstract: In order to study the propagation characteristics of short laser pulses in partially stripped plasma, parameters evolution equation of short laser pulses in partially ionized plasma was derived using variational method. The effect parameters of wakefield, relativistic self-focusing and intensity of partially stripped plasma were analyzed. The coupled evolution equations of the laser spot size and the pulse length were derived and the propagation of a short laser pulse in partially stripped plasma was analyzed under the effects of transverse wakefield(TWF) and longitudinal wakefield(LWF). The results show that laser pulse can be allowed to propagate in patitally stripped plasma only when a certain condition is satisfied. The evolution of the pulse length should be considered in partially stripped plasma. When laser pulse and plasma density is constant, with the increasing of ionization degree, wakefield will enhance the self-focusing of the laser pulse further. Longitudinal wakefield has more obvious effect on self-focusing of laser pulse than transverse wakefield. The results may be significant theoretically to the mechanism of ionization-induced injection and acceleration by an intense laser pulse.

HTML

Reference (22)

[1]	TAJIMA T, DAWSON J M. Laser electron accelerator[J].Physics Review Letters, 1979,43(4): 267-270.
[2]	NUCKOLLS J H, WOOD L, THIESSEN A R, et al. Laser compression of matter to super-high densities: thermonuclear (CTR) Applications[J].Nature, 1972,239(15):139-142.
[3]	TABAK M, HAMMER J, GLINSKY M E, et al. Ignition and high gain with ultrapowerful lasers[J].Physics Plasmas, 1994,1(5):1626-1634.
[4]	LINDL J D, Development of the indirect-drive approach to inertial confinement fusion and the target physics basis for ignition and gain[J]. Physics Plasmas, 1995,2(2):3933-4025.
[5]	ESAREY E, SPRANGLE P, KRALL J, et al. Overview of plasma-based accelerator concepts[J].IEEE Transactiong Plasma Science,1996,24(2):252-288.
[6]	HAO D Sh. A new accelerated mechanism of protons in high power laser-plasma [J]. Laser Technology, 2012, 36(4):653-656(in Chinese).
[7]	SPRANGLE P, HAFIZI B, PENANO J R, et al. Wakefield generation and GeV acceleration in tapered plasma channels[J].Physics Review, 2001,E63(5):056405.
[8]	MILCHBERG H M, DURFEE Ⅲ C G, MCILRATH T J. High-order frequency conversion in the plasma waveguide[J].Physics Review Letters,1995,75(13):2494-2497.
[9]	MAcKLIN J, KMETEC J, GORDON C. High-order harmonic generation using intense femtosecond pulses[J].Physics Review Letters,1993,70(6):766-769.
[10]	ZHOU J, PEATROSS J, MURNANE M M, et al. Enhanced high-harmonic generation using 25fs laser pulses[J].Physics Review Letters,1996,76(5):752-755.
[11]	SPRANGLE P, ESAREY E. Interaction of ultrahigh laser fields with beams and plasmas[J].Physics Fluids, 1992,B4(7):2241-2248.
[12]	HONG X R, XIE B S, ZHANG S, et al. Wakefield effects and solitary waves of an intense short laser pulse propagation in a plasma channel[J].Physics Plasmas,2011,18(10):103106.
[13]	HU Q L, XIAO G L, RUAN W, et al. One-dimensional EM solitons in ultrashort intense laser pulse-partially stripped plasmas[J].Physics Letters,2010,A374(7):965-968.
[14]	SPRANGLE P, ESAREY E, HAFIZI B. Propagation and stability of intense laser pulses in partially stripped plasmas[J].Physics Review,1997,E56(5):5894-5907.
[15]	SPRANGLE P, ESAREY E, HAFIZI B. Intense laser pulse propagation and stability in partially stripped plasmas[J].Physics Review Letters,1997,79(6):1046-1049.
[16]	MANGLES S P D, MURPHY C D, NAJMUDIN Z, et al. Monoenergetic beams of relativistic electrons from intense laser-plasma interactions[J].Nature, 2004,431(7008):535-538.
[17]	GEDDES C G R, TOTH C S, van TILBORG J, et al. Observations of longitudinal and transverse self-injections in laser-plasma wakefield accelerators[J].Nature, 2004,431(7008):538-541.
[18]	FAURE J, GLIEC Y, PUKHOV A, et al. A laser-plasma accelerator producing monoenergetic electron beams[J].Nature,2004,431(7008):541-544.
[19]	LU W, HUANG C, ZHOU M, et al. Nonlinear theory for relativistic plasma wakefields in the blowout regime[J].Physics Review Letters, 2006,96(16):165002-165005.
[20]	LEEMANS W P, NAGLER B, GONSALVES A J, et al. GeV electron beams from a centimetre-scale accelerator[J].Nature Physics, 2006,2(10):696-699.
[21]	LIU M P, ZHENG Z, LIU S Q. Effects of Relativistic and ponderomotive nonlinearities on an intense laser pulse propagation in a plasma channel[J]. Communications in Theoretical Physics,2012,58(10):569-572.
[22]	PALLAVI J, VIJAY S, AJAY K, et al. Self-focusing and compression of laser pulses in partially stripped plasma[J].Physics Plasmas, 2011,18(7):073105.

Propagation of short laser pulses in partially stripped plasma

Abstract

References

Proportional views

通讯作者: 陈斌, bchen63@163.com

Proportional views