Deciphering spatially resolved Lyman-alpha profiles in reionization analogs: the Sunburst Arc at cosmic noon

arXiv - PHYS - Astrophysics of Galaxies Pub Date : 2024-09-16 DOI:arxiv-2409.10604

E. Solhaug, H. -W. Chen, M. C. Chen, F. Zahedy, M. Gronke, M. -J. Hamel-Bravo, M. B. Bayliss, M. D. Gladders, S. López, N. Tejos

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Abstract

The hydrogen Lyman-alpha (Lya) emission line, the brightest spectral feature of a photoionized gas, is considered an indirect tracer of the escape of Lyman continuum (LyC) photons, particularly when the intergalactic medium is too opaque for direct detection. However, resonant scattering complicates interpreting the empirical properties of Lya photons, necessitating radiative transfer simulations to capture their strong coupling with underlying gas kinematics. In this study, we leverage the exceptional spatial resolution from strong gravitational lensing to investigate the connection between Lya line profiles and LyC leakage on scales of a few 100 pc in the Sunburst Arc galaxy at $z\sim2.37$. New optical echelle spectra obtained using Magellan MIKE show that both the LyC leaking and non-leaking regions exhibit a classic double-peak Lya feature with an enhanced red peak, indicating outflows at multiple locations in the galaxy. Both regions also show a central Gaussian peak atop the double peaks, indicating directly escaped Lya photons independent of LyC leakage. We introduce a machine learning-based method for emulating Lya simulations to quantify intrinsic dynamics ($\sigma_{\mathrm{int}}$), neutral hydrogen column density ($N_{\mathrm{HI}}$), outflow velocity ($v_{\mathrm{exp}}$), and effective temperature ($T$) across continuous parameter spaces. By comparing the spatially and spectrally resolved Lya lines in Sunburst, we argue that the directly escaped Lya photons originate in a volume-filling, warm ionized medium spanning $\sim1$ kpc, while the LyC leakage is confined to regions of $\lesssim200$ pc. These sub-kpc variations in Lya profiles highlight the complexity of interpreting integrated properties in the presence of inhomogeneous mixtures of gas and young stars, emphasizing the need for spatially and spectrally resolved observations of distant galaxies.

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解读再电离类似物中空间分辨的莱曼-阿尔法剖面：宇宙正午的旭日弧

氢莱曼-阿尔法（Lya）发射线是光离子化气体最亮的光谱特征，被认为是莱曼连续（LyC）光子逸出的间接示踪线，特别是当星系间介质太不透明而无法直接探测时。然而，共振散射使得解释涟光光子的经验特性变得复杂起来，这就需要进行辐射转移模拟，以捕捉它们与底层掩膜物质之间的强耦合。在这项研究中，我们利用强引力透镜的超高空间分辨率，研究了旭日弧星系在$z\sim2.37$时，Lya线谱与LyC泄漏之间在几百 pc尺度上的联系。利用麦哲伦MIKE获得的新的光学层析成像光谱显示，LyC泄漏区和非泄漏区都表现出典型的双峰Lya特征，并有一个增强的红色峰，这表明在星系的多个位置都有外流。这两个区域还在双峰之上显示出一个中心高斯峰，表明Lya光子直接外逸，与LyC泄漏无关。我们引入了一种基于机器学习的方法来模拟Lyasimulations，以量化跨连续参数空间的本征动力学（$\sigma_{mathrm{int}}$）、中性氢柱密度（$N_\{mathrm{HI}}$）、外流速度（$v_{mathrm{exp}}$）和有效温度（$T$）。通过比较 "旭日 "中空间和光谱分辨的涟漪线，我们认为直接逸出的涟漪光子源于充满太阳光的、温暖的电离介质，其范围为 $\sim1$ kpc，而涟漪光子的泄漏则局限于 $\lesssim$ 200 pc的区域。Lyaprofiles的这些亚kpc变化凸显了在不均匀的气体和年轻恒星混合物中解释综合性质的复杂性，强调了对遥远星系进行空间和光谱分辨观测的必要性。

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 - Astrophysics of Galaxies

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