Effect of Surface Plasma on Nanosecond Laser Ablation

For the first time, the effect of target surface plasma on nanosecond laser ablation is studied. Surface plasma was generated by a high-power cw fiber laser beam incident on an iron target. A comparison of laser ablation by nanosecond Nd:YAG laser pulses (1064 nm, 5 ns) was performed upon exposure to the cw laser and during its short-term (5 ms) turn off. It was found that the emission intensity twofold increases in the presence of surface plasma. The temperature and electron density of the laser plume induced by the nanosecond laser also increased.     

Electron Acceleration by Beating of Two Intense Cross-Focused Hollow Gaussian Laser Beams in Plasma

This paper presents propagation of two cross-focused intense hollow Gaussian laser beams(HGBs) in collisionless plasma and its effect on the generation of electron plasma wave(EPW) and electron acceleration process,when relativistic and ponderomotive nonlinearities are simultaneously operative. Nonlinear differential equations have been set up for beamwidth of laser beams, power of generated EPW, and energy gain by electrons using WKB and paraxial approximations. Numerical simulations have been carried out to investigate the effect of typical laser-plasma parameters on the focusing of laser beams in plasmas and further its effect on power of excited EPW and acceleration of electrons. It is observed that focusing of two laser beams in plasma increases for higher order of hollow Gaussian beams,which significantly enhanced the power of generated EPW and energy gain. The amplitude of EPW and energy gain by electrons is found to enhance with an increase in the intensity of laser beams and plasma density. This study will be useful to plasma beat wave accelerator and in other applications requiring multiple laser beams.     

激光诱导煤样等离子体的表征

以脉冲Nd·YAG激光器泵浦的光学参量发生/放大器输出为激发源,获得了一种家庭用煤样品的激光诱导等离子体(laser induced plasma,LIP)发射光谱。谱线线型呈洛伦兹线型,表明等离子体加宽以Stark展宽为主。利用发射谱线的Stark展宽和强度,通过测量等离子体不同位置的发射光谱,确定了等离子体温度和电子密度的空间分布,发现二者在垂直等离子体发光火焰方向相对火焰中心对称分布,沿发光火焰方向不具有对称分布的特点。发光火焰中心的等离子体温度和电子密度最大,且发光强度较大,因此利用光谱技术测量等离子体特征量时,宜采集火焰中心的发射光谱。样品中有些元素的发射谱线线型显示,等离子体中存在很强的自吸收现象,自吸收程度和激发波长及激光能量密切相关,激发波长接近谱线中心波长时,自吸收现象最明显;随激光能量的增加,发射光谱强度增加的同时,自吸收的程度也增大。把这些现象归因于原子跃迁概率的增大及激光强度增加引起的等离子体中粒子数密度的增大。自吸收现象导致实验观测到的发射谱线强度小于LIP的真实辐射强度,对等离子体进行测量时,应选取不存在自吸收现象的谱线,以便于提高测量准确度。     

Laser Self-Trapping for the Plasma Fiber Accelerator

A short-pulsed intense laser is injected into an underdense plasma to sustain a self-trapped photon channel. With either high-enough intensity or strong-enough focusing the optical beam causes total electron evacuation on the beam axis. Under appropriate conditions this laser and plasma fiber system can provide a slow wave structure of the electromagnetic wave that is suitable for high-energy acceleration.     

Supra—thermal Electron Generation at Moderate Laser Intensity

The effects of re-scattering on the supra-thermal electron (STE) produced in moderate laser fields are analytically considered (laser intensity I is up to 5.0×10¹⁶ W•cm^-2) with a simple model. The electron kinetic energy distribution given by the model is consistent to that given by the particle-in-cell simulation. Based on this fact, it is shown that the scattering of electron in intense laser by the ion in plasma plays an important role in the generation of STE in a moderate laser field.     

Bi靶激光等离子体极紫外光源以及碎屑辐射特性研究

激光等离子体极紫外光源具有体积小、稳定性高和输出波长可调节等优势,在极紫外光刻领域发挥着重要的作用。Bi靶激光等离子体极紫外光源在波长9～17 nm范围内具有较宽的光谱,可应用于制造极紫外光刻机过程中所需的极紫外计量学领域。利用平像场光谱仪和法拉第杯对Bi靶激光等离子体极紫外光源以及离子碎屑辐射特性进行了实验研究。在单脉冲激光打靶条件下,实验中观察到Bi靶激光等离子极紫外光谱在波长12.3 nm处出现了一个明显的凹陷,其对应着Si L-edge的吸收,是Bi元素光谱的固有属性。相应地在波长为11.8和12.5 nm位置处产生了两个宽带的辐射峰。研究了两波长光谱特性以及辐射强度随激光功率密度的变化。结果表明,在改变聚焦光斑大小实现不同激光功率密度（0.7×1010～3.1×1010 W·cm-2）过程中,当功率密度为2.0×1010 W·cm-2时两波长处的光辐射最强,其原因归结为Bi靶极紫外光辐射强度受激光能量用于支撑等离子膨胀的损失和极紫外光被等离子体再吸收之间的平衡制约所致。在改变激光能量实现不同激光功率密度过程中,由于烧蚀材料和产生两波长所需高阶离子随着功率密度的增加而增加,增强了两波长处的光辐射。进一步,研究了双脉冲激光对Bi靶极紫外光谱辐射特性影响,实验发现双脉冲打靶下原来在单脉冲打靶时出现在波长13～14 nm范围内的凹陷消失。最后,对单脉冲激光作用Bi靶产生极紫外光源碎屑角分布进行了测量。结果表明,当探测方向从靶面法线方向移动到沿着靶面方向上的过程中,探测到Bi离子动能依次减小,并且离子动能随激光脉冲能量降低而呈线性减小。此项研究有望为我国在研制极紫外光刻机过程所需的计量学领域提供技术支持和打下夯实的基础。     

Laser-Plasma Interaction in Presence of an Obliquely External Magnetic Field: Application to Laser Fusion without Radioactivity

In this paper, the nonlinear interaction of ultra-high power laser beam with fusion plasma at relativistic regime in the presence of obliquely external magnetic field has been studied. Imposing an external magnetic field on plasma can modify the density profile of the plasma so that the thermal conductivity of electrons reduces which is considered to be the decrease of the threshold energy for ignition. To achieve the fusion of Hydrogen-Boron (HB) fuel, the block acceleration model of plasma is employed. Energy production by HB isotopes can be of interest, since its reaction does not generate radioactive tritium. By using the inhibit factor in the block model acceleration of plasma and Maxwell's as well as the momentum transfer equations, the electron density distribution and dielectric permittivity of the plasma medium are obtained. Numerical results indicate that with increasing the intensity of the external magnetic field, the oscillation of the laser magnetic field decreases, while the dielectric permittivity increases. Moreover, the amplitude of the electron density becomes highly peaked and the plasma electrons are strongly bunched with increasing the intensity of external magnetic field. Therefore, the magnetized plasma can act as a positive focusing lens to enhance the fusion process. Besides, we find that with increasing θ-angle (from oblique external magnetic field) between 0 and 90°, the dielectric permittivity increases, while for θ between 90° and 180°, the dielectric permittivity decreases with increasing θ.     

侧吹气体对光纤激光修锐青铜金刚石砂轮等离子体特性影响

为了研究辅助侧吹氩气对光纤激光修锐青铜结合剂金刚石砂轮等离子体的影响,利用高速摄像机拍摄不同侧吹工艺参数下等离子体空间膨胀形态,结果表明：氩气降低了等离子体的膨胀高度,随着压力增加,等离子体的膨胀距离减小,等离子抑制作用增强。 利用光谱仪研究了等离子体发射光谱在砂轮径向上的最大值随氩气压力的变化情况,并根据Boltzmann斜线法和Stark展宽法,计算不同氩气压力下等离子体在砂轮径向上电子温度和电子数密度的最大值,结果表明：气体压力增大,等离子体光谱线强度先增大后减小,等离子体光谱线强度在0.2 MPa时达到峰值,较大的氩气压力明显降低等离子体电子温度和电子数密度,从而减小对砂轮表面形貌的影响。 利用超景深三维扫描仪观测添加侧吹气体前后砂轮表面形貌,结果表明：0.5 MPa侧吹氩气后,砂轮表面形貌质量明显优于未添加侧吹气体时。     

强激光等离子体耦合效应的数值模拟

 研究了高强度（10¹²(10^{14W/cm2）,纳秒脉冲(高斯型)激光与AI、 CH等离子体的耦合效应。采用一维双温、单流体力学方程组,数值模拟研究激光强度和波长对靶表面能量沉积和对等离子体特征参数的影响。激光等离子体耦合的主要机制有:轫致辐射、逆轫致辐射吸收、热扩散和电子、离子之间碰撞能量交换。给出了电子最高温度与光强的近似定量关系。}     

激光诱导Ni等离子体特性的研究

以Nd·YAG激光器的二倍频输出作为激发源,获得了激光诱导Ni等离子体的发射光谱,基于发射光谱,对等离子体电子激发温度和电子密度进行了测量,其典型值分别为3 714 K,4.67×1016 cm-3。测量了等离子体电子激发温度和电子密度的空间分布,发现沿垂直于激光传播方向的径向,随到中心点距离的增加,等离子体辐射的强度减小,但线型和线宽不变,表明等离子体电子激发温度和电子密度沿径向均匀分布。沿激光传播方向,随到样品表面距离的增加,等离子体辐射强度、电子激发温度和电子密度先增加后降低,在距样品表面1.5 mm处,达到最大值。采用激光诱导击穿光谱技术进行相关探测时,收集距离样品表面1.5 mm处的发射谱,有利于提高探测灵敏度。     

Parametric amplification of laser-driven electron acceleration in underdense plasma

A new mechanism is reported that increases electron energy gain from a laser beam of ultrarelativistic intensity in underdense plasma. The increase occurs when the laser produces an ion channel that confines accelerated electrons. The frequency of electron oscillations across the channel is strongly modulated by the laser beam, which causes parametric amplification of the oscillations and enhances the electron energy gain. This mechanism has a threshold determined by a product of beam intensity and ion density.     

保护条件变化的激光焊接等离子体光谱分析

保护气体在激光焊接过程中起重要的作用,保护条件的改变对焊接质量会有显著地影响。研究Nd∶YAG激光焊过程中保护条件的变化对激光等离子体的电子温度和电子密度等特征参数的影响,通过设计分步减小保护气流量的激光焊试验进行规律性研究,通过模拟实际可能发生的保护不良的激光焊试验进行验证性研究。在试验研究过程中,利用光谱仪采集激光焊接过程中产生的光致等离子体的光谱信息,通过相对光强法计算不同保护条件下等离子体的电子温度,通过斯塔克展宽机制计算不同保护条件下等离子体的电子密度。研究结果表明,保护条件的改变对Nd∶YAG激光焊接过程中产生的光致等离子体的电子温度和电子密度有重要影响,随着保护条件的变化,光致等离子体的电子温度和电子密度的平均值会发生变化,其波动幅度也会发生变化。在保护良好的条件下,等离子体的电子温度和电子密度均较小,且波动幅度也较小;在保护不良的条件下,等离子体的电子温度和电子密度都比较大,且波动幅度也比较大,这种变化的特征有助于对激光焊接过程进行质量监控。     

Non-uniform Influence of Prepulse Duration on a Nickel-Like Mo X-Ray Laser in XLIII

An experiment on a transient nickel-like Mo x-ray laser in the extreme light III (XL III) laser facility is analyzed, based on the two-dimensional hydrodynamic evolutions of a plasma under a non-uniform incident laser. Influences of the pulse duration and intensity on plasma scale length, electron density, temperature, as well as their distributions are investigated, based on which the pre-pulse character and delay time are determined according to the parameters of laser line focus on XLIII. It is found that the optimal intensity of the pre-pulse is 1.0TW/cm² with a duration of 500ps; a well modified pre-plasma can be obtained after 1.6ns under low quality line focus in the lab.     

激光能量对飞灰颗粒流中未燃碳LIBS检测影响研究

飞灰含碳量是评价锅炉燃烧效率的重要指标之一,对其进行在线测量有助于实时进行燃烧优化调整,从而提高整个机组的经济性和安全性。利用螺杆式给粉机搭建飞灰颗粒流含碳量测量台架,将脉冲激光直接作用于飞灰颗粒流,形成等离子体,利用激光诱导击穿光谱技术测量飞灰颗粒流中的含碳量信息。重点研究了激光能量对飞灰颗粒流中未燃碳有效激发和测量的影响规律。研究结果显示,在40～130 mJ能量的脉冲激光作用下,碳谱线强度随着激光能量的增大线性增强,而其信噪比则先增加后趋于稳定,无效光谱的剔除率则呈下降趋势。本实验条件下,激光能量在90～100 mJ之间,可得到较强的等离子体发射信号和较优的光谱数据利用率。因而激光能量与颗粒流的激发状态、碳元素特征谱线强度等密切相关。合理的激光能量有利于保证飞灰颗粒流的有效稳定激发,并获得具有良好信噪比的等离子体光谱信号。     

纳秒激光诱导空气等离子体的红外辐射特性研究

纳秒激光诱导空气等离子体存在从紫外、可见、近红外乃至射频微波的宽谱段辐射,但目前的研究大多关注紫外到可见波段的光谱辐射。激光等离子体作为一种新型的红外辐射源具有很多优势,相比于红外干扰弹以及红外干扰手段而言,空气等离子体红外辐射源可以灵活布置,成本低廉,因此研究空气等离子体的红外辐射特性就很有必要。针对目前脉冲激光诱导空气等离子体的红外干扰研究需要,对激光波长为532 nm的纳秒脉冲激光诱导空气等离子体的红外辐射特性进行实验研究,探讨激光能量对空气等离子体红外辐射强度的影响规律,以及空气等离子体红外辐射的角度分布特性,分析了等离子体红外辐射的可能产生机制。实验结果表明,激光诱导空气等离子体在950～1 700 nm范围内的红外光谱为线状谱和连续谱的叠加。其中线状谱主要是氮和氧的中性原子谱线,并且氮原子红外辐射占主导。随着激光能量的增加,由于空气击穿产生的氧和氮原子数量增加,导致空气等离子体红外辐射的谱线强度逐渐增大。随着红外探测角度的变化,在探测角度为75°时,OⅠ 1 128.63 nm和NⅠ1 246.96和1 362.42 nm谱线强度达到最大,在探测角度为120°时,NⅠ 1 011.46和1 053.96 nm谱线强度达到最大,这是因为空气等离子体红外辐射强度随探测角度变化呈现空间非对称性,表明空气等离子体内不同粒子的空间分布呈现非对称性。     

不同实验条件对激光诱导等离子体的影响机理研究

常温常压下,采用波长532 nm的Nd:YAG纳秒激光器激发诱导空气中的铝合金,由高分辨率的光谱仪和ICCD对等离子体发射光谱采集和实现光电转换。研究激光能量、ICCD门延迟和聚焦透镜到样品表面的距离(lens-to-sample distance,LTSD)对谱线信号强度和等离子体电子温度的影响,并分析了产生影响的物理机制。结果表明,固定ICCD门延迟和LTSD,随着激光能量的增大,谱线强度和电子温度均增大;计算结果表明,当激光能量从20 mJ增加到160 mJ时,原子谱线Al I 396.15 nm,Mg I 518.36 nm,离子谱线Mg II 279.54 nm谱线强度相较于20 mJ分别提高了12.83,6.45,10.56倍。固定激光能量和LTSD,ICCD门延迟在100~4000 ns范围内变化时,随着延迟的增加,谱线强度和等离子体电子温度均呈指数形式衰减。固定ICCD门延迟和激光能量,采用焦距为75 mm的聚焦透镜,研究了LTSD对等离子体参数的影响机理。结果表明,聚焦透镜到样品的距离对等离子体的谱线强度和电子温度有较大的影响。等离子体的特征谱线强度和等离子体的电子温度的变化规律基本一致,分别在聚焦透镜到样品表面的距离为73 mm和79 mm处取得峰值,并在73 mm处对应最大值。     

激光偏振状态对磁化等离子体中电磁孤波的影响

强激光与等离子体之间相互作用,能够产生各种参量不稳定性过程和非线性效应。利用Karpman方法推导出横场包络所满足的非线性控制性方程,在一维情况下,获得孤波解。对孤波解进行分析,发现波包孤子的半宽反比于振幅;分析磁化等离子体中各参量对孤波半宽的影响。结果表明,在右旋圆偏振激光情况下,随着电子数密度的增大,孤波的半宽逐渐减小,而当磁场强度增大时,孤波的半宽逐渐增大;在左旋圆偏振激光情况下,随着电子数密度的增大,孤波的半宽逐渐增大,而当磁场强度增大时,孤波的半宽逐渐减小。     

线状镁激光等离子体电子密度的空间分辨测量

本文报道在ＬＦ１２激光装置线聚焦打靶情况下，利用ＭｇⅪ共振线和互组合线的强度比推得的激光等离子体电子密度的空间分布轮廓。将此结果和点聚焦打靶得到的结果比较发现二者区别不大。本文还讨论了电子复合伴线、光厚等因素对电子密度测量的影响。     

气体压强对纳秒激光诱导空气等离子体特性的影响

环境气体的压强对激光诱导等离子体特性有重要影响.基于发射光谱法开展了气体压强对纳秒激光诱导空气等离子体特性影响的研究,探讨了气体压强对空气等离子体发射光谱强度、电子温度和电子密度的影响.实验结果表明,在10-100 kPa空气压强条件下,空气等离子体发射光谱中的线状光谱和连续光谱依赖于气体压强变化,且原子谱线和离子谱线强度随气体压强的变化有明显差别.随着空气压强增大,激光击穿作用区域的空气密度增加,造成激光诱导击穿空气几率升高,从而等离子体辐射光谱强度增大.空气等离子体膨胀区域空气的约束作用,增加了等离子体内粒子间的碰撞几率以及能量交换几率,并且使离子-电子-原子的三体复合几率增加,因此造成原子谱线OⅠ777.2 nm与NⅠ821.6 nm谱线强度随着气体压强增大而增大,在80 kPa时谱线强度最高,随后谱线强度缓慢降低.而离子谱线N Ⅱ 500.5 nm谱线强度在40 kPa时达到最大值,气体压强大于40 kPa后,谱线强度随压强增加而逐渐降低.空气等离子体电子密度均随压强升高而增大,在80 kPa后增长速度变缓.等离子体电子温度在30 kPa时达到最大值,气体压强大于30 kPa后,等离子体电子温度逐渐降低.研究结果可为不同海拔高度的激光诱导空气等离子体特性的研究提供重要实验基础,为今后激光大气传输、大气组成分析提供重要的技术支持.     

超短脉冲强激光场中电子剩余能计算

为了控制光场感应电离等离子体的温度以使得基于光场感应电离机制的X射线激光辐射获得更高的增益值,利用准静态隧道电离模型,定量计算了电子剩余能量与激光偏振参量、波长(频率)、激光强度以及电离介质电离能的变化关系。计算结果表明线偏振短波长激光以及高电离能介质产牛的等离子体中电子剩余能比较低,因此适合用作复合机制X射线激光;对于低价离子存偏振度α介于0～1之间的某一处最高,因此,可以通过调整偏振度α,获得某一椭圆偏振光,会更有利于基于光场感应电离电子碰撞机制X射线激光增益的提高。