Voit G M, Bryan G L
Space Telescope Science Institute, 3700 San Martin Drive, Baltimore, Maryland 21218, USA.
Nature. 2001 Nov 22;414(6862):425-7. doi: 10.1038/35106523.
Clusters of galaxies are thought to contain about ten times as much dark matter as baryonic matter. The dark component therefore dominates the gravitational potential of a cluster, and the baryons confined by this potential radiate X-rays with a luminosity that depends mainly on the gas density in the cluster's core. Predictions of the X-rays' properties based on models of cluster formation do not, however, agree with the observations. If the models ignore the condensation of cooling gas into stars and feedback from the associated supernovae, they overestimate the X-ray luminosity because the density of the core gas is too high. An early episode of uniformly distributed supernova feedback could rectify this by heating the uncondensed gas and therefore making it harder to compress into the core, but such a process seems to require an implausibly large number of supernovae. Here we show how radiative cooling of intergalactic gas and subsequent supernova heating conspire to eliminate highly compressible low-entropy gas from the intracluster medium. This brings the core entropy and X-ray luminosities of clusters into agreement with the observations, in a way that depends little on the efficiency of supernova heating in the early Universe.
星系团被认为包含的暗物质大约是重子物质的十倍。因此,暗物质成分主导着星系团的引力势,而受此引力势束缚的重子会以一种主要取决于星系团核心气体密度的光度辐射X射线。然而,基于星系团形成模型对X射线性质的预测与观测结果并不相符。如果模型忽略了冷却气体凝聚成恒星以及相关超新星的反馈,它们就会高估X射线光度,因为核心气体的密度过高。早期均匀分布的超新星反馈可以通过加热未凝聚的气体来纠正这一点,从而使其更难压缩到核心区域,但这样一个过程似乎需要数量多得难以置信的超新星。在这里,我们展示了星系际气体的辐射冷却以及随后的超新星加热如何共同作用,从星系团内介质中消除高度可压缩的低熵气体。这使得星系团的核心熵和X射线光度与观测结果相符,而且这种方式几乎不依赖于早期宇宙中超新星加热的效率。