Aims. Within the framework of compact-object accretion disks, we calculate plasma environment effects on the atomic structure and decay parameters used in the modeling of K lines in lowly charged iron ions, namely Fe? II –Fe? VIII . Methods. For this study, we used the fully relativistic multiconfiguration Dirac–Fock method approximating the plasma electron–nucleus and electron-electron screenings with a time-averaged Debye-Hückel potential. Results. We report modified ionization potentials, K-threshold energies, wavelengths, radiative emission rates, and Auger widths for plasmas characterized by electron temperatures and densities in the ranges 10~(5)???10~(7)K and 10~(18)???10~(22)cm~(?3). In addition, we propose two universal fitting formulae to predict the IP and K-threshold lowerings in any elemental ion. Conclusions. We conclude that the high-resolution X-ray spectrometers onboard the future XRISM and ATHENA space missions will be able to detect the lowering of the K edges of these Fe ions due to the extreme plasma conditions occurring in the accretion disks around compact objects.
展开▼
机译:目标。在紧凑型物体积极磁盘的框架内,我们计算对k线材建模的原子结构和衰减参数的等离子体环境效应,即Fe? II -FE? VIII。方法。对于本研究,我们使用了近似等离子体电子 - 核和电子筛分的完全相对论的多组配置Dirac-Fock方法,其具有时间平均的Debye-Hückel电位。结果。我们报告改进的电离电位,k阈值能量,波长,辐射排放率和螺旋梁宽度,其特征在于电气温度和范围内的密度10〜(5)??? 10〜(7)k和10〜(18 )??? 10〜(22)cm〜(?3)。此外,我们提出了两个通用拟合公式,以预测任何元素离子的IP和k阈值下降。结论。我们得出结论,在未来的XRISC和ATHENA空间任务上的高分辨率X射线光谱仪将能够检测由于在紧凑型物体周围的吸积磁盘中发生的极端血浆条件,检测这些FE离子的k边缘的降低。
展开▼
