Department of Astronomy, University of Massachusetts, Amherst, MA 01003, USA.
Proc Natl Acad Sci U S A. 2010 Apr 20;107(16):7168-73. doi: 10.1073/pnas.0914255107. Epub 2010 Mar 8.
This presentation reviews Chandra's major contribution to the understanding of nearby galaxies. After a brief summary on significant advances in characterizing various types of discrete x-ray sources, the presentation focuses on the global hot gas in and around galaxies, especially normal ones like our own. The hot gas is a product of stellar and active galactic nuclear feedback--the least understood part in theories of galaxy formation and evolution. Chandra observations have led to the first characterization of the spatial, thermal, chemical, and kinetic properties of the gas in our galaxy. The gas is concentrated around the galactic bulge and disk on scales of a few kiloparsec. The column density of chemically enriched hot gas on larger scales is at least an order magnitude smaller, indicating that it may not account for the bulk of the missing baryon matter predicted for the galactic halo according to the standard cosmology. Similar results have also been obtained for other nearby galaxies. The x-ray emission from hot gas is well correlated with the star formation rate and stellar mass, indicating that the heating is primarily due to the stellar feedback. However, the observed x-ray luminosity of the gas is typically less than a few percent of the feedback energy. Thus the bulk of the feedback (including injected heavy elements) is likely lost in galaxy-wide outflows. The results are compared with simulations of the feedback to infer its dynamics and interplay with the circumgalactic medium, hence the evolution of galaxies.
本演讲回顾了钱德拉在理解近邻星系方面的主要贡献。在简要总结了在刻画各种类型离散 X 射线源方面的重大进展后,演讲重点介绍了星系内外的全局热气体,特别是像我们自己这样的普通星系。热气体是恒星和活动星系核反馈的产物,这是星系形成和演化理论中最不为人理解的部分。钱德拉观测首次对星系中气体的空间、热、化学和动力学特性进行了刻画。气体集中在星系核球和星系盘上,尺度在几千秒差距左右。在更大的尺度上,化学成分丰富的热气体的柱密度至少小一个数量级,表明根据标准宇宙学,它可能无法解释星系晕中预测的大部分缺失重子物质。对于其他近邻星系,也得到了类似的结果。热气体的 X 射线发射与恒星形成率和恒星质量密切相关,表明加热主要是由恒星反馈引起的。然而,观测到的气体的 X 射线光度通常小于反馈能量的百分之几。因此,大部分反馈(包括注入的重元素)可能在星系范围内的外流中损失。结果与反馈的模拟进行了比较,以推断其动力学及其与星系际介质的相互作用,从而推断星系的演化。