Feeding and Small-scale Feedback in Low-Luminosity AGNs
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[1] R. K. Smith,et al. UPDATED ATOMIC DATA AND CALCULATIONS FOR X-RAY SPECTROSCOPY , 2012, 1207.0576.
[2] R. Penna,et al. SAGITTARIUS A* ACCRETION FLOW AND BLACK HOLE PARAMETERS FROM GENERAL RELATIVISTIC DYNAMICAL AND POLARIZED RADIATIVE MODELING , 2010, 1007.4832.
[3] M. Gounelle,et al. THE CHROMIUM ISOTOPIC COMPOSITION OF THE UNGROUPED CARBONACEOUS CHONDRITE TAGISH LAKE , 2011 .
[4] Tuscaloosa,et al. RESOLVING THE BONDI ACCRETION FLOW TOWARD THE SUPERMASSIVE BLACK HOLE OF NGC 3115 WITH CHANDRA , 2011, 1106.3069.
[5] W. Mathews,et al. COSMIC RAY DIFFUSION FRONTS IN THE VIRGO CLUSTER , 2011, 1105.5866.
[6] A. Kravtsov,et al. FUEL EFFICIENT GALAXIES: SUSTAINING STAR FORMATION WITH STELLAR MASS LOSS , 2010, 1011.1252.
[7] M. Ruszkowski,et al. Galaxy motions, turbulence and conduction in clusters of galaxies , 2010, 1008.5016.
[8] F. Baganoff,et al. INFLOW–OUTFLOW MODEL WITH CONDUCTION AND SELF-CONSISTENT FEEDING FOR Sgr A* , 2010, 1004.0702.
[9] L. Ho,et al. RADIATIVELY INEFFICIENT ACCRETION IN NEARBY GALAXIES , 2009, 0906.4104.
[10] P. Hopkins,et al. QUASARS ARE NOT LIGHT BULBS: TESTING MODELS OF QUASAR LIFETIMES WITH THE OBSERVED EDDINGTON RATIO DISTRIBUTION , 2008, 0809.3789.
[11] E. Quataert,et al. Spherical accretion with anisotropic thermal conduction , 2008, 0804.1353.
[12] L. Ho. Nuclear Activity in Nearby Galaxies , 2008, 0803.2268.
[13] P. Hopkins,et al. A Cosmological Framework for the Co-Evolution of Quasars, Supermassive Black Holes, and Elliptical Galaxies. I. Galaxy Mergers and Quasar Activity , 2007, 0706.1243.
[14] Sergei Nayakshin,et al. Variable accretion and emission from the stellar winds in the Galactic Centre , 2007, 0705.0769.
[15] L. Ho,et al. The Mass Function of Active Black Holes in the Local Universe , 2007, 0705.0020.
[16] T. Paumard,et al. Stellar and wind properties of massive stars in the central parsec of the Galaxy , 2006, Proceedings of the International Astronomical Union.
[17] P. Hopkins,et al. Fueling Low-Level AGN Activity through Stochastic Accretion of Cold Gas , 2006, astro-ph/0603180.
[18] P. Hopkins,et al. A Unified, Merger-driven Model of the Origin of Starbursts, Quasars, the Cosmic X-Ray Background, Supermassive Black Holes, and Galaxy Spheroids , 2005, astro-ph/0506398.
[19] S. Pellegrini,et al. Nuclear Accretion in Galaxies of the Local Universe: Clues from Chandra Observations , 2005, astro-ph/0502035.
[20] A. Eckart,et al. Stellar Dynamics in the Central Arcsecond of Our Galaxy , 2003, astro-ph/0306214.
[21] R. Narayan. Why Do AGN Lighthouses Switch Off , 2002, astro-ph/0201260.
[22] M. Gilfanov,et al. Lighthouses of the universe : the most luminous celestial objects and their use for cosmology : proceedings of the MPA/ESO/MPE/USM Joint Astronomy Conference held in Garching, Germany, 6-10 August 2001 , 2002 .
[23] R. Narayan,et al. Thermal Conduction in Clusters of Galaxies , 2001, astro-ph/0110567.
[24] Prague,et al. Continuous stellar mass-loss in N -body models of galaxies , 2001, astro-ph/0107160.
[25] R. Narayan,et al. Self-similar Accretion Flows with Convection , 1999, astro-ph/9912449.
[26] E. Quataert,et al. Convection-dominated Accretion Flows , 1999, astro-ph/9912440.
[27] Roger D. Blandford,et al. On the fate of gas accreting at a low rate on to a black hole , 1998, astro-ph/9809083.
[28] J. E. Pringle,et al. Theory of black hole accretion disks , 1999 .
[29] John Kormendy,et al. Inward Bound—The Search for Supermassive Black Holes in Galactic Nuclei , 1995 .
[30] P. Padovani,et al. Stellar Mass Loss in Elliptical Galaxies and the Fueling of Active Galactic Nuclei , 1993 .
[31] P. Crane,et al. Detection of an unresolved nuclear radio source in M31 , 1992 .
[32] A. Renzini,et al. Winds, outflows, and inflows in X-ray elliptical galaxies. I , 1991 .
[33] Rashid Sunyaev,et al. Black holes in binary systems. Observational appearance , 1973 .
[34] E. Pian,et al. LIGHTHOUSES OF THE UNIVERSE: THE MOST LUMINOUS CELESTIAL OBJECTS AND THEIR USE FOR COSMOLOGY , 2022 .