Bo-Eun Choi, Jessica K. Werk, Kirill Tchernyshyov, J. Xavier Prochaska, Yong Zheng, Mary E. Putman, Drummond B. Fielding and Jay Strader
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We address the blending of absorption lines with the ISM by jointly fitting Voigt profiles to all absorption components. We present our metallicity estimates for the DHI of the Milky Way based on detailed photoionization modeling of the absorption from ionized metal lines and ionization-corrected total hydrogen columns. Generally, the gas clouds show a large scatter in metallicity, ranging between 0.04 and 3.2 Z⊙, implying that the DHI consists of a mixture of gaseous structures having multiple origins. We estimate the inflow and outflow timescales of the DHI ionized clouds to be 6–35 Myr. 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引用次数: 0
摘要
银河系星际介质(ISM)和环星系介质(即星盘-光环界面(DHI))边界弥漫电离气体中的金属,是驱动银河喷泉的反馈过程的重要示踪剂。然而,由于银河系 ISM 的遮挡和影响总氢柱密度的不确定电离校正,该区域的金属性测量具有挑战性。在这项工作中,我们利用高分辨率吸收光谱对位于同一球状星团中的脉冲星和紫外光目标的电子柱密度进行频散测量,精确测量了电子柱密度对中性氢柱密度的电离修正。我们通过联合拟合所有吸收成分的 Voigt 曲线,解决了吸收线与 ISM 的混合问题。我们根据电离金属线和电离校正总氢柱吸收的详细光电离模型,提出了银河系 DHI 的金属度估计值。一般来说,气体云的金属性散布很大,范围在 0.04 到 3.2 Z⊙之间,这意味着 DHI 是由多种来源的气体结构混合而成的。我们估计DHI电离云的流入和流出时间尺度为6-35 Myr。我们报告探测到了一个具有超太阳金属性的流入云,这表明了银河喷泉机制,而至少有一个低金属性的流出云(Z < 0.1 Z⊙)对银河喷泉和反馈模型提出了挑战。
Metallicity Mapping of the Ionized Diffuse Gas at the Milky Way Disk–Halo Interface
Metals in the diffuse, ionized gas at the boundary between the Milky Way’s interstellar medium (ISM) and circumgalactic medium, known as the disk–halo interface (DHI), are valuable tracers of the feedback processes that drive the Galactic fountain. However, metallicity measurements in this region are challenging due to obscuration by the Milky Way ISM and uncertain ionization corrections that affect the total hydrogen column density. In this work, we constrain ionization corrections to neutral hydrogen column densities using precisely measured electron column densities from the dispersion measures of pulsars that lie in the same globular clusters as UV-bright targets with high-resolution absorption spectroscopy. We address the blending of absorption lines with the ISM by jointly fitting Voigt profiles to all absorption components. We present our metallicity estimates for the DHI of the Milky Way based on detailed photoionization modeling of the absorption from ionized metal lines and ionization-corrected total hydrogen columns. Generally, the gas clouds show a large scatter in metallicity, ranging between 0.04 and 3.2 Z⊙, implying that the DHI consists of a mixture of gaseous structures having multiple origins. We estimate the inflow and outflow timescales of the DHI ionized clouds to be 6–35 Myr. We report the detection of an infalling cloud with supersolar metallicity that suggests a Galactic fountain mechanism, whereas at least one low-metallicity outflowing cloud (Z < 0.1 Z⊙) poses a challenge for Galactic fountain and feedback models.