通过数值求解一维含时Schrdinger方程,研究了具有较长脉宽双色激光脉冲与氢原了相互作用产生的高次谐波和阿秒(as)脉冲.这里的双色激光脉冲由一束基频钛宝石主脉冲与另一束红外附加脉冲构成.研究发现,当合成脉冲的脉宽选为12fs时,选取合适的附加脉冲波长,合成电场的振幅在始末端时间段能被大幅抑制,仪中间部分的电场对谐波谱平台区和截止位置起主要贡献.通过分析合成脉冲电场始末端时间段抑制的机理,进一步扩展不合成脉冲脉宽到60 as,并得到160 as的孤立短脉冲.这是迄今为止在孤立阿秒脉冲产生研究中所采用的最长脉宽.该方案中的合成脉冲等效于单一5 fs短脉冲的作用,却克服了5 fs脉冲低输出能量导致的阿秒脉冲能最低的困难.
We theoretically investigate the high-order harmonic and attosecond pulse generation by numerically solving the one-dimensional time-dependent Schrdinger equation from a hydrogen atom in a two-color laser field,which is synthesized by adding a suitable multicycle infrared pulse to a multicycle 800 nm fundamental pulse.Our results clearly show that when there are 12 Ti:sapphire optical cycles in the pulse envelope,by adding a suitable second optical field,the electric field of the synthesized pulse presents three- segments,and only amplitude of the electric field in middle segment makes a major contribution to the plateau and cutoff region of the harmonic spectrum.By analyzing the compression mechanism of two-color electric field,we further enlarge the duration of the synthesized pulse to 60 fs,and obtain a single 160 as short pulse.This has been the longest pulse duration used for obtaining single attosecond pulse so far.Here the effect of synthesized pulses is similar to the effect of single 5 fs ultrashort pulse.This scheme greatly reduces the requirements for the pump laser system used traditionally for generating an isolated attosecond pulse,and it allows us to use a well-established conventional high-power pumping laser.