Attosecond Inner-Shell Lasing at Angstrom Wavelengths

arXiv - PHYS - Optics Pub Date : 2024-09-10 DOI:arxiv-2409.06914

Thomas M. Linker, Aliaksei Halavanau, Thomas Kroll, Andrei Benediktovitch, Yu Zhang, Yurina Michine, Stasis Chuchurka, Zain Abhari, Daniele Ronchetti, Thomas Fransson, Clemens Weninger, Franklin D. Fuller, Andy Aquila, Roberto Alonso-Mori, Sebastien Boutet, Marc W. Guetg, Agostino Marinelli, Alberto A. Lutman, Makina Yabashi, Ichiro Inoue, Taito Osaka, Jumpei Yamada, Yuichi Inubushi, Gota Yamaguchi, Toru Hara, Ganguli Babu, Devashish Salpekar, Farheen N. Sayed, Pulickel M. Ajayan, Jan Kern, Junko Yano, Vittal K. Yachandra, Matthias F. Kling, Claudio Pellegrini, Hitoki Yoneda, Nina Rohringer, Uwe Bergmann

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Abstract

Since the invention of the laser nonlinear effects such as filamentation, Rabi-cycling and collective emission have been explored in the optical regime leading to a wide range of scientific and industrial applications. X-ray free electron lasers (XFELs) have led to the extension of many optical techniques to X-rays for their advantages of angstrom scale spatial resolution and elemental specificity. One such example is XFEL driven population inversion of 1s core hole states resulting in inner-shell K${\alpha}$ (2p to 1s) X-ray lasing in elements ranging from neon to copper, which has been utilized for nonlinear spectroscopy and development of next generation X-ray laser sources. Here we show that strong lasing effects, similar to those observed in the optical regime, can occur at 1.5 to 2.1 angstrom wavelengths during high intensity (> ${10^{19}}$ W/cm${^{2}}$) XFEL driven inner-shell lasing and superfluorescence of copper and manganese. Depending on the temporal substructure of the XFEL pump pulses, the resulting inner-shell X-ray laser pulses can exhibit strong spatial inhomogeneities as well as spectral inhomogeneities and broadening. Through 3D Maxwell Bloch theory we show that the observed spatial inhomogeneities result from X-ray filamentation, and that the spectral broadening is driven by Rabi cycling with sub-femtosecond periods. These findings indicate that we have generated Angstrom-wavelength x-ray pulses (containing ${10^{6}}$ - ${10^{8}}$ photons) in the strong lasing regime, some of them with pulse lengths of less than 100 attoseconds.

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埃级波长的阿秒级内壳激光

自激光器发明以来，人们一直在探索光学体系中的非线性效应，如灯丝效应、拉比循环效应和集合发射效应，从而产生了广泛的科学和工业应用。由于 X 射线自由电子激光器（XFEL）具有埃级空间分辨率和元素特异性的优势，因此许多光学技术都延伸到了 X 射线领域。其中一个例子是 XFEL 驱动的 1s 核孔态的种群反转导致了从氖到铜等元素的内壳 K${α}$ （2p 到 1s）X 射线激光，这已被用于非线性光谱学和下一代 X 射线激光源的开发。在这里，我们展示了在高强度（>${10^{19}}$ W/cm${^{2}}$）XFEL驱动的铜和锰的内壳激光和超荧光过程中，在1.5到2.1埃波长处会出现类似于在光学环境中观察到的强激光效应。通过三维麦克斯韦布洛赫理论，我们发现观测到的空间不均匀性是由 X 射线丝状化产生的，而光谱增宽则是由亚飞秒周期的拉比循环驱动的。这些发现表明，我们已经在强激光系统中产生了埃级波长的 X 射线脉冲（包含 ${10^{6}}$ - ${10^{8}}$ 光子），其中一些脉冲长度小于 100 阿秒。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Optics

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