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seto6
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can anyone explain quasar feedback.. having some trouble.
Quasar Feedback: the Missing Link in Structure Formation
We consider the impact of quasar outflows on structure formation. Such outflows are potentially more important than galactic winds, which appear insufficient to produce the level of preheating inferred from X-ray observations of galaxy clusters. Using a simple analytical model for the distribution of quasars with redshift, coupled with a one-dimensional Sedov-Taylor model for outflows, we are able to make robust statements about their impact of on structure formation. As large regions of the IGM are heated above a critical entropy of approximately 100 keV cm^2, cooling become impossible within them, regardless of changes in density. On quasar scales, this has the effect of inhibiting further formation, resulting in the observed fall-off in their number densities below z = 2. On galaxy scales, quasar feedback fixes the turn-over scale in the galaxy luminosity function (L_*) as the nonlinear scale at the redshift of strong feedback. The galaxy luminosity function then remains largely fixed after this epoch, consistent with recent observations and in contrast to the strong evolution predicted in more standard galaxy-formation models. Finally, strong quasar feedback explains why the intracluster medium is observed to have been pre-heated to entropy levels just above S_crit, the minimum excess that would not have been erased by cooling. The presence of such outflows is completely consistent with the observed properties of the Lyman-alpha forest at z ~ 2, but is expected to have a substantial and detectable impact on Compton distortions observed in the microwave background and the multiphase properties of the "warm-hot" (z=0) circumgalactic medium.
Quasar Feedback: More Bang for Your Buck
Observations have established that the masses of supermassive black holes (BHs) are tightly correlated with various host galaxy properties (Magorrian et al. 1998; Ferrarese & Merritt 2000; Gebhardt et al. 2000; Hopkins et al. 2007a; Aller & Richstone 2007). Together with constraints indicating that most of the BH mass is assembled in optically bright quasar1 phases (Soltan 1982; Salucci et al. 1999; Yu & Tremaine 2002; Hopkins et al. 2006b), this has led to the development of models where feedback processes from accretion self-regulated BH growth at a critical mass (Silk & Rees 1998; Di Matteo et al. 2005;Murray et al. 2005). Gas inflows triggered by some process fuel rapid BH growth, until feedback begins to expel nearby gas and dust. This “blowout” results in a short-lived, bright optical quasar that, having expelled its fuel supply, fades and leaves a remnant on the observed BH host correlations (Hopkins et al. 2005a,c). These scenarios have been able to explain many quasar observables, including luminosity functions, lifetimes, and BH mass functions (Hopkins et al. 2005b, 2006c, 2008b, 2009; Volonteri et al. 2006; Menci et al. 2003; Somerville et al. 2008; Lapi et al. 2006; Tortora et al. 2009).
Quasar feedback refers to the process by which the powerful energy emitted from a quasar, a distant and extremely luminous object in space, affects the surrounding gas and dust, altering the formation of new stars and regulating the growth of galaxies.
Quasar feedback occurs when the strong radiation and winds produced by a quasar interact with the gas and dust in its host galaxy. This can heat up or remove gas, preventing it from collapsing and forming new stars. It can also compress gas, triggering star formation in other parts of the galaxy.
Quasar feedback plays a crucial role in regulating the growth and evolution of galaxies. It helps to balance the formation of new stars and the growth of supermassive black holes, and can also affect the chemical composition and dynamics of galaxies.
Scientists use various methods to study quasar feedback, including observations with telescopes, computer simulations, and theoretical models. They analyze the properties of quasars, their host galaxies, and the surrounding gas and dust to understand how quasar feedback affects galactic evolution.
While the study of quasar feedback is primarily focused on understanding the evolution of galaxies, it can also have practical applications. For example, studying quasar feedback can aid in the development of more accurate models of galaxy formation and help us understand the role of black holes in the universe.