Cho B I, Cho M S, Kim M, Chung H-K, Barbrel B, Engelhorn K, Burian T, Chalupský J, Ciricosta O, Dakovski G L, Hájková V, Holmes M, Juha L, Krzywinski J, Lee R W, Nam Chang Hee, Rackstraw D S, Toleikis S, Turner J J, Vinko S M, Wark J S, Zastrau U, Heimann P A
Center for Relativistic Laser Science, Institute for Basic Science (IBS), Gwangju 61005, Korea.
Department of Physics and Photon Science, Gwangju Institute of Science and Technology, Gwangju 61005, Korea.
Phys Rev Lett. 2017 Aug 18;119(7):075002. doi: 10.1103/PhysRevLett.119.075002. Epub 2017 Aug 16.
A nonlinear absorber in which the excited state absorption is larger than the ground state can undergo a process called reverse saturable absorption. It is a well-known phenomenon in laser physics in the optical regime, but is more difficult to generate in the x-ray regime, where fast nonradiative core electron transitions typically dominate the population kinetics during light matter interactions. Here, we report the first observation of decreasing x-ray transmission in a solid target pumped by intense x-ray free electron laser pulses. The measurement has been made below the K-absorption edge of aluminum, and the x-ray intensity ranges are 10^{16} -10^{17} W/cm^{2}. It has been confirmed by collisional radiative population kinetic calculations, underscoring the fast spectral modulation of the x-ray pulses and charge states relevant to the absorption and transmission of x-ray photons. The processes shown through detailed simulations are consistent with reverse saturable absorption, which would be the first observation of this phenomena in the x-ray regime. These light matter interactions provide a unique opportunity to investigate optical transport properties in the extreme state of matters, as well as affording the potential to regulate ultrafast x-ray free-electron laser pulses.
一种激发态吸收大于基态吸收的非线性吸收体可经历一种称为反饱和吸收的过程。这在光学领域的激光物理学中是一种众所周知的现象,但在X射线领域更难产生,在X射线领域,快速的无辐射核心电子跃迁在光与物质相互作用期间通常主导着粒子动力学。在此,我们报告了首次观察到在由强X射线自由电子激光脉冲泵浦的固体靶中X射线透射率降低的现象。该测量是在铝的K吸收边以下进行的,X射线强度范围为10¹⁶ - 10¹⁷ W/cm²。碰撞辐射粒子动力学计算证实了这一点,突出了与X射线光子的吸收和透射相关的X射线脉冲和电荷态的快速光谱调制。通过详细模拟展示的过程与反饱和吸收一致,这将是在X射线领域首次观察到这种现象。这些光与物质的相互作用为研究极端物质状态下的光学传输特性提供了独特机会,同时也为调控超快X射线自由电子激光脉冲提供了潜力。
