Angular momentum distribution in strong-field frustrated tunneling ionization

Using the classical-trajectory Monte Carlo model, we have theoretically studied the angular momentum distribution of frustrated tunneling ionization(FTI) of atoms in strong laser fields. Our results show that the angular momentum distribution of the FTI events exhibits a double-hump structure. With this classical model, we back traced the tunneling coordinates, i.e., the tunneling time and initial transverse momentum at tunneling ionization. It is shown that for the events tunneling ionized at the rising edge of the electric field,the final angular momentum exhibits a strong dependence on the initial transverse momentum at tunneling.While for the events ionized at the falling edge, there is a relatively harder recollision between the returning electron and the parent ion, leading to the angular momentum losing the correlation with the initial transverse momentum. Our study suggests that the angular momentum of the FTI events could be manipulated by controlling the initial coordinates of the tunneling ionization.     

超导薄膜磁场穿透深度的双线圈互感测量

磁场穿透深度是联系超导体宏观电动力学与微观机制的重要物理量,其精确测量对于研究超导机理以及探索超导应用具有重要意义.在众多的磁场穿透深度测量方法中,双线圈互感法具有测量精度高、技术相对成熟、对样品没有破坏等优点,可被用于细致地研究超导薄膜的磁场穿透深度对温度、掺杂、外延应力等参量的依赖关系.本文首先简要介绍了双线圈互感法的基本原理,指出该方法的测量精度主要受系统几何参数及薄膜边缘漏磁的影响;之后对自主设计搭建的透射型双线圈互感装置进行了系统的校验,并详细说明了其测量精度:对于厚度为100 nm,穿透深度为150 nm的典型薄膜样品,穿透深度绝对值的测量误差小于10%;最后通过测量NbN超导薄膜的磁场穿透深度进一步检验了装置的精度,分析表明穿透深度的测量值与文献报道结果符合.