Summary form only given. Recent investigations of the propagation of high-power femtosecond infrared (IR) laser pulses in air show that the dynamical interaction between nonlinear self-focusing and plasma defocusing causes an initial beam to breakup spatially into several filaments, or light strings, which maintain themselves over long distances via a turbulent optical light guide. It has been observed experimentally that femtosecond light strings in turn produce plasma channels by multi-photon ionization (MPI) along their direction of propagation with lengths ranging from tens of centimeters to several meters, and diameters around a hundred microns. For high-intensity (e.g. 10/sup 14/ W/cm/sup 2/) femtosecond IR laser input pulses, MPI is the dominant mechanism of plasma creation. If these channels attain a finite dipole moment then this could explain the recently observed electromagnetic pulse (EMP) from light string induced plasmas. The lifetime of the observed plasma channels is around a nanosecond in keeping with the duration of the observed EMP. One anticipates that the central frequency of the EMP will be related to the plasma frequency of the channel, but the frequency has not been determined experimentally as of yet.
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机译:仅提供摘要表格。最近对高功率飞秒红外(IR)激光脉冲在空气中传播的研究表明,非线性自聚焦和等离子体散焦之间的动态相互作用会导致初始光束在空间上分解成几根细丝或灯串,从而使它们自身保持在通过湍流的光学导光管实现长距离传输。实验上已经观察到,飞秒灯串通过多光子电离(MPI)沿着其传播方向依次产生等离子通道,其长度范围从几十厘米到几米,直径约100微米。对于高强度(例如10 / sup 14 / W / cm / sup 2 /)飞秒IR激光输入脉冲,MPI是产生等离子体的主要机制。如果这些通道达到有限的偶极矩,则可以解释最近从灯串诱导的等离子体中观察到的电磁脉冲(EMP)。所观察到的等离子体通道的寿命大约为纳秒,与所观察到的EMP的持续时间保持一致。人们预计EMP的中心频率将与通道的等离子体频率相关,但是该频率尚未通过实验确定。
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