Gravitational heating, clumps, overheating. Yuval Birnboim (Harvard Smithsonian Center for Astrophysics) Avishai Dekel (Hebrew University)

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Gravitational heating, clumps, overheating Yuval Birnboim (Harvard Smithsonian Center for Astrophysics) Avishai Dekel (Hebrew University)

Basic idea: Cooling flow Clusters need additional energy to reduce cooling rate and SFR of CD galaxy Possible mechanisms: AGN feedback (Deus ex Machina) Transferring energy from outer halo to the center Conduction (probably ruled out) Heating by mass & energy injection from the outer-halo. Accreted cold clumps can pump energy to the center

See also: magnetic fields

Outline 1. Tapping into the gravitational energy reservoir 2. Coupling the inner halo to the outer world 3. Global and local stability of heating mechanisms 4. 1D Hydro-simulation results

Outline 1. Tapping into the gravitational energy reservoir 2. Coupling the inner halo to the outer world 3. Global and local stability of heating mechanisms 4. 1D Hydro-simulation results

1. Tapping into the gravitational energy reservoir Halos of Mvir 10 13 Mʘ have enough Egrav to compensate for cooling Calculation parameters: profile: NFW total w isothermal gas Accretion rate: Wechsler et al. 2002 f f f gas clump bar = 0.05 Z= 0.3Zʘ = 0.05 z= 0 = f gas + f clump R penetration = 0.1R vir Dekel & Birnboim 2008, see also Khochfar & Ostriker 2008

Outline 1. Tapping into the gravitational energy reservoir 2. Coupling the inner halo to the outer world 3. Global and local stability of heating mechanisms 4. 1D Hydro-simulation results

2. Coupling the inner halo to the outer world Heating by baryonic cold clumps Physical processes of clump: 1. Hydrodynamic drag 2. Jeans mass (Bonnor-Ebert) 3. K-H/R-T instabilities and clump fragmentation 4. DF (marginally works) 5. Conduction/evaporation Requirements for effective heating: 1. Enough energy 2. Qusai-Hydrostatic halo 3. Enough clumps 4. Correct mass range of clumps

Hydrodynamic drag F drag = 1 2 C d ρ halo π r 2 clump v shear Trans-sonic C drag 1 Turbulent heating Shock heating 1 v c s

Clump Survivability 1) Energy goes to the hot diffuse component 2) Clump fragments after repelling ones weight in diffuse gas Murray & Lin 2004

2. Coupling of the inner halo to the outer world (cntd.) Monte-Carlo of many clumps (static halo) The fiducial case: Mv=10 13 M, mc=10 7 M, fb=0.1, fc=0.05

2. Coupling of the inner halo to the outer world (cntd.) Open questions: How to produce these clumps Mass deposition is near center (can we have our cake and eat it?) Need to start the process with realistic I.C. Can the halo remain dynamically stable when H/C 0. Clumps alternatives: cold flows splashing at the inner halo large scale turbulence conduction

Origin of clumps DM subhalos will loose gas Cooling fragmentation in filaments, outskirts of cluster can be birthplace of clumps Note: missing baryon problem in clusters!

Outline 1. Tapping into the gravitational energy reservoir 2. Coupling the inner halo to the outer world 3. Global and local stability of heating mechanisms 4. 1D Hydro-simulation results

3. Global and local stability of heating mechanisms Clump Heating, Radiation heating by AGN etc. are proportional to density Fields (65), Conroy & Ostriker (07) note that such gas is cooling unstable: hydrostatic equilibrium : cooling : heating : 2 Λ( T ) ρ ρt Cooling instability is always a heating instability! ρ unstable heating entropy inversion convection ρ 1.5 = const H C ρ 0.5

Outline 1. Tapping into the gravitational energy reservoir 2. Coupling the inner halo to the outer world 3. Global and local stability of heating mechanisms 4. 1D Hydro-simulation results

4. 1D Hydro-simulation results Hydra 1D spherical Lagrangian code New components: Sub-grid model for clumps clump shells are DM shells with extra forces heating, momentum transfer mass injection when clumps disintegrate Lagrangian AMR (shell splitting) Convection (1D Mixing length theory)

4. 1D Hydro-simulation results Mvir=1e15M No clumps very efficient heating! (>1e45 erg/sec since z=1) 20% clumps of mc=1e8m Clumps + conv 4e12 1.2e12M

4. 1D Hydro-simulation results Effects of convection

4. 1D Hydro-simulation results Mvir=3e14M No clumps 10% clumps of mc=1e7m Clumps + conv 2.8e12 1.4e12M

4. 1D Hydro-simulation results Effects of convection

Outline 1. Tapping into the gravitational energy reservoir 2. Coupling the inner halo to the outer world 3. Global and local stability of heating mechanisms 4. 1D Hydro-simulation results

Summary Gravitational energy can balance cooling Clumps couple naturally to the inner parts of clusters Cooling instability is local, heating invokes convection. But there is no global effect heating strangles central galaxy and shuts down star formation Fun, cool problem to work on

5. Cold Flows and the greater scheme No hot hydrostatic gas: Cold flows rapid star formation hot gas halo: energy input wins over cold mass input star formation shut-down