19.6nm波长类氖锗X光激光光源理论模拟

 波长19.6nm的类氖锗X光激光适合作为诊断激光等离子体界面不稳定性的光源。用经过实验检验的系列程序对预-主短脉冲驱动类氖锗进行了系统的优化设计和理论分析。采用2%~3%的预脉冲强度，6~8ns的预-主脉冲时间间隔，在4×10¹³W/cm²功率密度驱动下, 波长19.6nm增益区的宽度可以超过60μm，增益区的维持时间可以达到90ps。对于16mm长的平板靶，增益系数可达11.8/cm；弯曲靶增益系数可达13.3/cm；单靶小增益长度积可达21.3，单靶就可以获得饱和增益。采用双靶对接，其小讯号增益可达38.4，可以获得深度饱和增益，能满足应用演示所需的X光激光光源。     

放电参数对毛细管放电泵浦的软X射线激光的影响

 以哈尔滨工业大学可调谐激光技术国家重点实验室中的Marx发生器的放电脉冲波形为基础，理论上模拟计算了在不同放电参数下充氩气的毛细管放电产生的等离子体状态和类氖氩离子3p_3s跃迁线的增益系数的时空演变过程。中心模型中，选取内径为3.1 mm 的陶瓷毛细管并充入初始密度为1.07×10^-6g·cm^-3的氩气，电流脉冲峰值为27.81 kA，脉冲宽度为61.4 ns。改变放电参数进行模拟，结果表明：上升前沿越陡，则增益系数越大，电流脉冲上升时间在20~40 ns，电流峰值在25~40 kA，电流脉冲宽度在50~70 ns范围内，毛细管放电产生的等离子体状态比较理想，可获得较高的增益系数。     

模拟ps激光驱动的类氖锗19.6 nm X光激光

 瞬态电子碰撞激发产生X光激光的机制可以极大减少X光激光的泵浦能量。模拟了脉宽为1 ps，波长1.053 μm的钕玻璃激光驱动的类氖锗X光激光。模拟表明，在临界面附近可以产生高达60 cm ^-1的增益，还计算了X光激光在等离子体中的传播，计算表明X光激光在等离子体中的折射效应仍然是影响X光激光输出强度及分布的重要因素。     

2ω1ω激光驱动的类氖锗19.6 nm X光激光

 类氖离子的X光激光理论研究可以为类镍X光激光提供有益启示。设计了一系列瞬态电子碰撞激发类氖锗19.6 nm X光激光的实验，采用2ω1ω泵浦方式，即预脉冲采用倍频钕玻璃激光，主脉冲采用基频，用新开发的瞬态电子碰撞激发类氖锗的系列程序进行了模拟，并与1ω1ω驱动的情况进行了比较。模拟表明, 2ω1ω泵浦方案使类氖锗19.6 nm Ｘ光激光的小信号增益系数增大为1ω1ω方案的1.6倍,增益区也转移到了更高的电子密度区,是获得更短波长X光激光的一种有效方法。     

掠入射较高功率密度驱动Ni-like AgX射线激光的理论研究

 用系列程序对掠入射方式驱动亚稳态类镍银碰撞激发机制进行了研究。继低功率密度驱动获得有效增益系数为23.8 cm^-1结果之后，在4.3×10¹³ W·cm^-2较高功率密度驱动时，增益区移到驱动激光折返点附近，有效增益系数达到40 cm^-1以上，比正入射提高了2.4倍。用50 J激光能量驱动单靶，就能达到有效增益长度积为40的深度饱和增益。     

飞秒激光激发空气电离的阈值研究

报道在脉宽50fs—22ps，波长800nm脉冲激光作用下的空气电离阈值的研究结果.利用探测等离子体发光信号的方法，实验测量了激发空气电离所需的阈值激光强度.结果表明，当激光脉冲宽度从50fs增加到22ps时，阈值光强I_th从8.7×10¹⁴W/cm²下降到2.7×10¹³W/cm²；I_th经历了由迅速降低逐渐发展为缓慢降低的过程.在50fs—1p     

掠入射低功率密度驱动Ni-like AgX射线激光的理论研究

 用系列程序对掠入射方式驱动亚稳态类镍银的碰撞激发机制进行数值模拟。结果发现：与正入射方式相比，掠入射在1.2×10¹³ W·cm^-2低功率密度驱动时，驱动激光能量主要沉积在增益区附近，可以大幅度提高增益区的电子温度，也可以大幅度提高增益系数。通过对预主脉冲时间间隔和掠入射角的优化，采用10.5 ns延迟时间和16°的掠入射角，可使有效增益系数达到23.8 cm^-1，比正入射提高84％。用13 J驱动激光能量就可以获得增益长度积为23.8的深度饱和增益。     

低强度激光泵浦类Ni离子X光激光实验

 在试运行的神光Ⅱ装置上,采用新设计的凸柱面透镜列阵均匀线聚焦系统, 用两束激光焦线叠加和双靶对接等技术,以预主脉冲激光驱动方式,在(5～8)×10¹³W/cm²的较低强度激光泵浦条件下,观测到Ni-like　Dy、Er、Yb的软X光激光输出,测得波长5.02nm类Ni-Yb和波长5.86nm类Ni-Dy的软X光激光的增益系数分别为1.6cm^-1和1.4cm^-1     

类氖-锗电子碰撞激发X光激光的增益特性

 电子碰撞激发X光激光的增益特性依赖于电子密度Ne、电子温度Te、增益区宽度D R和介质速度梯度dv/dz等四个表征等离子体内部状态的参数。以类氖-锗离子为例研究了反转和增益特性对Te、Ne的依赖关系，并在典型的增益区宽度（D R=100 μm）和介质速度梯度（dv/dz=1.3×10⁹s^-1）下讨论了共振线俘获对增益特性影响，给出波长为19.6nm, 23.2nm和23.6nm三条激光线的增益目标区域。还讨论了双电子复合过程对离子布居的重要影响。     

长波长激光驱动Ni-like Ag 13.9 nmX射线激光的理论研究

 为了进一步深入理解掠入射驱动碰撞机制的特点与长处，以基频光正入射驱动为参照，用系列程序研究了6 mm和3 mm激光正入射驱动类镍银碰撞激发机制。在波长6 mm的激光正入射驱动下，激光能量直接沉积到增益区，大大提高了增益区的电子温度；以5 J驱动能量，获得有效增益系数为20.7 cm^-1的高增益和有效增益长度积为41.4的深度饱和增益，与波长1.053 mm的正入射相比，以19%的驱动能量，使有效增益系数提高了60%。在波长3 mm的激光正入射驱动下，激光能量沉积到增益区附近，大大提高了增益区的电子温度；以15 J驱动能量，获得有效增益系数为21.2 cm^-1的高增益和有效增益长度积为42.4的深度饱和增益，与波长1.053 mm的正入射相比，以57%的驱动能量，使有效增益系数提高64%。     

Plasma channel formed by ultraviolet laser pulses at 193 nm in air

The propagation of picosecond deep ultraviolet laser pulse at wavelength of 193 nm in air is numerically investigated. Long plasma channel can be formed due to the competition between Kerr self-focusing and ionization induced defocusing. The plasma channel with electron density of above 10^13/cm^3 can be formed over 70 m by 50-ps, 20-mJ laser pulses. The fluctuation of laser intensity and electron density inside ultraviolet （UV） plasma channel is significantly lower UV laser by air is considered in the simulation and it the limit of the length of plasma channel. than that of infrared pulse. The linear absorption of is shown that the linear absorption is important for the limit of the length of plasma channel.     

Cl/HN3/I2全气相化学激光体系的化学动力学模拟计算

 对Cl/HN₃/I₂产生NCl(a)/I激光的过程进行了化学动力学计算，主要考察了Cl,HN₃和I₂的初始粒子数密度及其配比对小信号增益系数的影响。结果发现,当温度为400K, 初始Cl粒子数密度为1×10¹⁵，1×10¹⁶和1×10¹⁷cm^-3时,小信号增益系数分别达到1.6×10^-4,1.1×10^-3和1.1×10^-2cm^-1，获得最佳小信号增益系数的HN₃和I₂的初始粒子数密度分别为初始Cl粒子数密度的1～2倍和2%～4%。同时，对Cl，HN₃和I₂配比对小信号增益系数和增益持续时间的影响进行了讨论。     

超短超强脉冲激光在空气中产生的电离通道的寿命研究

对超短超强激光脉冲在大气中传播时形成的电离通道的寿命进行了理论研究.综合考虑了通道中自由电子，正离子，负离子的复合，自由电子和中性分子的吸附以及在后续 激光作用下的退吸附过程.推导出了退吸附激光强度恒定时通道中带电离子密度的速率方程 的解析解.计算结果表明，通过引入退吸附激光抑制电子和中性分子的吸附作用能够在微秒 的时间尺度上将电子密度维持在10¹²—10¹³cm^-3的水平，在相同的波长 和平均功率下，短脉冲序列的退吸附效果要略好于连续激光 关键词： 等离子体通道 复合 吸附 退吸附 寿命     

Particle simulation on electron acceleration process by the laser ponderomotive force in inhomogeneous underdense plasma layers

The mechanism of electron ponderomotive acceleration due to increasing group velocity of laser pulse in inhomogeneous underdense plasma layers is studied by two-dimensional relativistic parallel particle-in-cell code. The electrons within the laser pulse move with it and can be strongly accelerated ponderomotively when the duration of laser pulse is much shorter than the duration of optimum condition for acceleration in the wake. The extra energy gain can be attributed to the change of laser group velocity. More high energy electrons are generated in the plasma layer with descending density profile than that with ascending density profile. The process and character of electron acceleration in three kinds of underdense plasma layers are presented and compared.     

X-ray laser studies at LLE

New target geometries for collisional excitation X-ray laser experiments (in nickel) were proposed, analyzed, and experimentally studied on the glass development laser. The new geometries are designed to yield a higher gain and reduced refraction due to (1) a higher plasma density, (2) a wide lateral density profile, and (3) a concave lateral density profile. These new geometries were (a) two parallel exploding (thin) foils, irradiated from one side only, (b) two ablating (thick) foils, one of which was irradiated on its inner face, and (c) and exploding foil in front of an ablating foil, irradiated by a single laser beam incident on the thin foil. Long-line-focus experiments are described. Theoretical developments included development of a ray-tracing code for an amplifying medium of varying lateral density profile and prediction of high gain on new type transitions in neon-like ions, involving the excitation of an inner (2 s) electron     

Electron excitation by a multi passage laser beam in a plasma

The limits put by optical guiding, and channel guiding mechanisms on the Laser Wakefield Acceleration (LWFA) technique are imposed on the Resonant Laser Wakefield Acceleration (RLWFA) scheme. Energy gained by the electrons in both schemes are calculated and compared. It has presented that in the RLWFA case, the electrons gain more and more energy after each traversal of the laser pulse and the electrons in a plasma gain about 3 GeV after 10 passages of the laser pulse. They gain 13 GeV when the laser light makes 50 passages and 26 GeV after the laser beam traverses the plasma 100 times. Moreover, the channel guiding mechanism is integrated to the RLWFA scheme and together with diffraction guiding a model for electron acceleration is proposed. Received 13 September 2000 and Received in final form 27 October 2000     

Theoretical study of Ni-like Ag 13.9nm TCE x-ray laser driven by two picosecond pulses

The Ni-like Ag 13.9nm x-ray laser has been previously demonstrated that the higher gain near critical surface contributes little to the amplification of the x-ray laser because of severe refraction. In this paper, the transient collision excitation (TCE) Ni-like Ag 13.9nm x-ray laser is simulated, driven by two 3ps short pulse preceded by a 330ps long prepulse, optimization of the peak to peak delay time of the two short pulses is made to get the best results. Simulation indicates that by producing lowly ionized preplasma with smoothly varying electron density, it is possible to decrease electron density gradient in higher density region, and thus higher gains near this region could be utilized, and if the main short pulse is delayed by 900ps, local gains where electron density larger than ～ 4×10²⁰cm^-3 could be utilized.     

Self-focusing, channel formation, and high-energy ion generation in interaction of an intense short laser pulse with a He jet

Using interferometry, we investigate the dynamics of interaction of a relativistically intense 4-TW, 400-fs laser pulse with a He gas jet. We observe a stable plasma channel 1 mm long and less than 30 microm in diameter, with a radial gradient of electron density approximately 5 x 10(22) cm(-4) and with an on-axis electron density approximately ten times less than its maximum value of 8 x 10(19) cm(-3). A high radial velocity of the surrounding gas ionization of approximately 3.8 x 10(8) cm/s has been observed after the channel formation, and it is attributed to the fast ions expelled from the laser channel and propagating radially outward. We developed a kinetic model which describes the plasma channel formation and the subsequent ambient gas excitation and ionization. Comparing the model predictions with the interferometric data, we reconstructed the axial profile of laser channel and on-axis laser intensity. The estimated maximum energy of accelerated ions is about 500 keV, and the total energy of the fast ions is 5% of the laser pulse energy.     

超短超强激光导引及对电子加速的影响

使用粒子模拟程序对30 fs超短超强激光在均匀与抛物型两种密度分布等离子体中的传输, 以及在稳定传输状态下尾场的电子注入与加速形成的电子能谱进行了模拟与分析. 固定入射激光束斑尺寸, 在(0.4-2)×10¹⁹/cm³等离子体密度范围, 对比分析了归一化峰值强度从1-6范围的激光脉冲在上述两种密度分布等离子 体中传输时激光束斑尺寸的演化, 结果表明抛物型分布的等离子体密度通道能够对超短超强脉冲实现良好的导引, 有利于高能电子加速. 对于较高密度情况,即使在均匀等离子体中依靠相对论自聚 焦等机制也可以实现良好的自导引传输,有利于实验简化以及产生更大电量的加速电子.