Essential observations of the Lyman continuum

arXiv: Astrophysics Pub Date : 2008-12-10 DOI:10.1063/1.3154070

S. McCandliss

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引用次数: 1

Abstract

Concurrent observations of Lyman continuum (LyC) and Lyman-alpha (Lya) emission escaping from star-forming systems at low redshift are essential to understanding the physics of reionization at high redshift (z >~ 6). Some have suggested reionization is dominated by numerous small galaxies with LyC escape fractions f_e ~ 10%, while others suggest mini-quasars with higher f_e might also play a role. At z > 3, direct observation of LyC leakage becomes progressively more improbable due to the increase of intervening Ly limit systems, leaving Lya as the primary diagnostic available to the James Webb Space Telescope for exploring the epoch of reionization. If a quantitative relationship between escaping LyC and Lya emission can be established at low z, then the diagnostic power of Lya as a LyC proxy at high z can be fully realized. Past efforts to detect f_e near z ~ 3 have been fruitful but observations at low redshift have been less so. We discuss the sensitivity requirements for detecting LyC leak in the far- and near-UV as a function of redshift 0.02 = 0.01 as estimated from UV luminosity functions. UV observations are essential to understanding of the physics of LyC escape and the ultimate goal of identifying the source(s) responsible for reionization.

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莱曼连续体的基本观测

同时观测Lyman连续体(LyC)和Lyman-alpha (Lya)辐射对于理解高红移(z >~ 6)时再电离的物理特性至关重要。一些人认为再电离主要是由许多LyC逃逸分数为f_e ~ 10%的小星系主导，而另一些人则认为f_e较高的迷你类星体也可能起作用。在z > 3时，由于中间Ly极限系统的增加，LyC泄漏的直接观测变得越来越不可能，使得Lya成为詹姆斯韦伯太空望远镜探索再电离时代的主要诊断。如果能在低z下建立逸出LyC与Lya发射之间的定量关系，那么就能充分实现Lya作为高z下LyC代理的诊断能力。过去在z ~ 3附近探测f_e的努力取得了丰硕的成果，但在低红移的观测却不太成功。我们讨论了检测远紫外和近紫外中LyC泄漏的灵敏度要求，作为从紫外光度函数估计的红移0.02 = 0.01的函数。紫外观测对于理解LyC逸出的物理性质和确定再电离源的最终目标是至关重要的。

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: Astrophysics

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