Tang Xiangyu, Wang Kan, Li Baochang, Chen Yanbo, Lin C D, Jin Cheng
Opt Lett. 2021 Oct 15;46(20):5137-5140. doi: 10.1364/OL.441365.
We identify optimal conditions for the generation and isolation of attosecond pulses in an overdriven ionized medium. In a high-pressure and highly ionized gas, the spatiotemporal wavefront rotation of a driving laser can be optimized, leading to complete spatial separation of successive attosecond bursts in the far field. The resulting isolated attosecond pulses (IAPs) are much more divergent such that they are spatially separated from the driving laser in the far field. We show that the time delay of near-field harmonic emission along the radial distance determines the divergence of the attosecond burst in the far field. The generated IAPs are phase matched upon propagation in the second half of the gas medium. Validity of the generation scheme is tested at different carrier-envelope phases for a few-cycle laser pulse and by synthesizing the fundamental and its second harmonic field for a long-duration pulse.
我们确定了在过驱动电离介质中产生和分离阿秒脉冲的最佳条件。在高压和高度电离的气体中,驱动激光的时空波前旋转可以得到优化,从而在远场中实现连续阿秒脉冲串的完全空间分离。由此产生的孤立阿秒脉冲(IAP)发散得多,以至于它们在远场中与驱动激光在空间上分离。我们表明,沿径向距离的近场谐波发射的时间延迟决定了远场中阿秒脉冲串的发散。所产生的IAP在气体介质后半段传播时实现了相位匹配。对于几周期激光脉冲,在不同的载波包络相位下测试了产生方案的有效性,并通过合成长持续时间脉冲的基频及其二次谐波场进行了测试。