Photoelectron -- residual-ion entanglement in streaked shake-up ionization of helium

arXiv - PHYS - Atomic Physics Pub Date : 2024-09-05 DOI:arxiv-2409.03622

Hongyu Shi, Uwe Thumm

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Abstract

Streaked photoelectron emission spectra access the correlated dynamics of photoelectrons and residual target electrons with attosecond temporal resolution. We calculated ab initio single-ionization spectra for photoemission from helium atoms by co-linearly polarized ultrashort XUV and assisting few-femtosecond IR pulses. Distinguishing direct and shake-up ionization resulting in ground-state and excited (n=2,3) He+ residual ions, respectively, we examined the effects of the correlated photoemission dynamics on the photoelectron phase-accumulation as a function of the observable photoelectron detection direction and kinetic energy, and XUV-IR pulse delay. We tracked the dynamical evolution of the residual ion in relative streaked photoemission delays and found dominant contributions for shake-up emission from the residual ion - photoelectron interaction. These are in very good and fair agreement, respectively, for n=2 and n=3 shake-up photoemission along the pulse-polarization directions, with previous experimental and theoretical investigations [Ossiander et. al. 2017] and reveal a strong photoemission-direction dependence for shake-up ionization due to the coupling between the photoelectron and evolving residual-ion charge distribution in the IR-laser field.

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氦的条纹振荡电离中的光电子-残余离子纠缠

条纹光电子发射光谱以阿秒级的时间分辨率获取光电子和残余靶电子的相关动力学。我们计算了氦原子在共线性偏振超短 XUV 和辅助微秒红外脉冲下的光电子发射的 ab initio 单电离光谱。我们区分了直接电离和震荡电离，分别产生了基态和激发态（n=2,3）的 He+ 残余离子，并考察了相关光电子发射动力学对光电子相位累积的影响，这种影响是可观测到的光电子探测方向和动能以及 XUV-IR 脉冲延迟的函数。我们跟踪了残余离子在相对条纹状光发射延迟中的动力学演变，发现残余离子-光电子相互作用对震荡发射的主要贡献。这与之前的实验和理论研究[Ossiander 等人，2017 年]在 n=2 和 n=3 震荡光发射沿脉冲偏振方向的情况下分别具有很好和一般的一致性，并揭示了由于光电子与红外激光场中不断演化的残余离子电荷分布之间的耦合作用，震荡电离具有很强的光发射方向依赖性。

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arXiv - PHYS - Atomic Physics

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