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X-ray Signatures of Feedback in Intracluster Gas Megan Donahue Michigan State University Collaborators: Mark Voit, Ken Cavagnolo, Steven Robinson, Don Horner (GSFC)
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X-ray Signatures of Feedback Metals in the ICM The ICM Luminosity - Temperature relationship. ICM entropy profiles and ICM bubbles.
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Clusters of galaxies Most massive, gravitationally-bound structures in the universe (~10 15 Mo) Hot gas outweighs the stars by a factor ~10 Dark matter outweighs the baryons by a factor ~ 8.
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ICM enriched on all scales 22 clusters w/Beppo-SAX Consistent Fe abundances Central excess consistent w/production by BCG. DeGrandi et al. 2001; 2004
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ICM enriched at high redshift Little evolution seen between z=0.3-1.3. Tozzi et al. 2003; Ettori, et al. 2005
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Abundance Patterns (Tamura et al. 2004) [Si/Fe], [S/Fe] solar [O/Fe] 0.4-0.7 solar in core of cool clusters; solar elsewhere. No trend with T > 2 keV Consistent with Ia and core-collapse supernova yields + star formation rates scaled from the field. (See ASCA results in Baumgartner et al. astro- ph/0309166 for contrary view.) XMM EPIC & RGS spectra, 22 clusters
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ICM Luminosity - Temperature Relation Gravity-only physics predicts L ~ T 2. Allowing radiation to cool the gas modifies the relation. e.g. Voit & Bryan 2001
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Galaxy Formation and the ICM Cooling and condensation into stars brings the L-T relation into agreement w/observations. However, cooling alone produces too many stars (Rees & White 1978; Balogh 2001). Star formation contributes metals and energy to the ICM: this feedback alone may regulate star formation in most galaxies.
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Galaxy Formation and the ICM: Questions Even with feedback from star formation, simulations still predict too much star formation in central dominant galaxies (e.g. Kravtsov 2005). Feedback in “cooling flows”: the ICM in the centers of most X-ray clusters are radiating too brightly to be supported without additional energy input.
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“Cooling Flows” Clusters with short central cooling times (t c <t H ). Regular, relaxed, luminous X-ray clusters with peaked central X-ray surface brightness. Fairly common, often with central radio sources and H nebulae in their cores. The radiation losses must be stabilized by feedback.
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Observed “cooling flow” spectra (XMM) Peterson et al. 2003 FeXVII and other lines from 1 keV gas not present. Two-temperature or “truncated” cooling flow (at ~T/3 - T/2)
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Cluster gas cools… Temperature gradients from Chandra and XMM observations. Mass cooling rates closer to star formation rates. Gas cooler than ~1 keV not seen or is very faint. The cooling times are still short. What keeps this gas from cooling further?
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Hydra A z=0.0522 50 kpc Radio Sources & Cluster Cores Can AGN balance radiative cooling in cluster cores? Bubbles in the ICM: (McNamara, Sarazin, Blanton) Heating occurs, but it’s not clear how the AGN compensates for radiative losses. AGN may be the primary culprit in quenching the cooling in cluster cores: but how to tell? Abell 2052 z=0.0353 50 kpc
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Radio-quiet cluster cores Peres et al. 1998: 23 clusters with cooling rates > 100 solar masses/year 13: emission line nebulae & strong central radio source 2: strong central radio source but no optical line emission (A2029, A3112) 3: emission lines but weak central radio source. (A478, A496, A2142) 5: no emission lines and little or no radio activity. (A644, A1650, A1651, A1689, A2244)
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Radio-quiet cluster cores Peres et al. 1998: 23 clusters with cooling rates > 100 solar masses/year 13: emission line nebulae & strong central radio source 2: strong central radio source but no optical line emission (A2029, A3112) 3: emission lines but weak central radio source. (A478, A496, A2142) 5: no emission lines and little or no radio activity. (A644, A1650, A1651, A1689, A2244)
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Chandra Observations Chose 2 symmetric, relaxed clusters without radio sources, A1650 and A2244. ACIS-S observations sufficient to obtain >150,000 counts for radial deprojection of spectra and surface brightness. Temperature and metallicity gradients measured at lower resolution than density gradient.
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A2244 & A1650 Feedback free? Radio quiet -- upper limits or detections a factor of 30 or more below the others Z = 0.095 and 0.085 KT ~ 5-6 keV
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What might have been: Fossil radio lobes and/or X-ray cavities suggestive of earlier radio activity. Temperature gradients sufficient to quench cooling via conduction. Very low central entropy values, suggesting that these clusters are on the verge of a heating episode.
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What is No fossil lobes out to ~100 kpc A1650 A2244 Donahue, et al. 2005
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What is No temperature gradients: limited, if any, conduction. Donahue, et al. 2005
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Entropy Specific entropy (Tn -2/3 ) is more closely related to heating and cooling than temperature alone. S = (Heat)/T = (3/2) Nk [ ln(Tn -2/3 )] –Only radiative cooling can reduce entropy –Only heat input (e.g. shocks) can increase entropy –Compression in a gravitational potential changes T but not Tn -2/3 (adiabatic). –S is directly related to t cool (small S(T), short t cool ) –Convective stability condition: dS/dr > 0 Cooling time t c = (14 Gyr) (S/81 keV cm 2 ) 3/2 (T keV ) -1
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Entropy Gradients Cool cores with feedback evidence show a remarkable consistency in their entropy profiles: S(r) = S 0 + (r/r 1 ) –S 0 ~ 10 keV cm 2 – ~ 0.9 - 1.3 is about what one expects as a result of structure formation outside the core (but not necessarily inside the core). Almost all have non-zero S 0.
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Interpretation of profiles Similarity of profiles could be used to argue against episodic heating. No evidence for entropy inversions r > 10 kpc: suggests energy injection can’t just happen at the center. Entropy floors, small entropy inversions, bubbles show current energy injection.
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Iron Gradients Significant iron gradients, increasing toward the core measured in most of these systems. The presence of a gradient suggests lack of disturbance (e.g. major mergers.) Quasi-stable core gas?
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What do we see? High central entropy! 35-50 keV cm 2
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What do we see? T~5-6 keV => t cool > 10 9 years
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Comparison L R vs. Central Entropy L R vs. Power-Law Slope
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Significant Iron Gradients
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What happened? These cluster cores have not yet cooled to low entropy, and will trigger an outburst in the future. OR The AGN in these clusters have a very low duty cycle, requiring enormous energy injection by AGN in the past.
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Do radio jets heat the ICM? Perseus Cluster & 3C 84Sound Waves in Perseus 10 kpc
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Dramatic Heating Events MS0735 (McNamara et al.)Hydra A (Nulsen et al.)
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AGN Heating in Groups Radio-loud groups (circles) tend toward the low-L, high-T side of L-T relation Croston et al. 2004
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Chandra Entropy Profiles Core entropy profiles very regular Entropy inversions are minor and lie at r < 10 kpc
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Episodic Heating t 10 8 yr (K / 10 keV cm 2 ) 3/2 (T / 5 keV) -1 Heating episodes required every ~10 8 yr Central entropy level remains near input level for most of duty cycle Central entropy input cannot greatly exceed 10-20 keV cm 2
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Entropy Jump Condition K 2 + 0.84 K 1 K - 0.16 K 1 v2v2 3(4 ) 2/3 v2v2
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Core Density Structure Core density profile: (r) ~ 1/r (r) = r (r) ~ 3 x10 -3 g cm -2
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Zones of AGN Heating for r ~ const. Luminosity dominated: L ~ r 2 v 3 K ~ 29 keV cm 2 L 45 2/3 3 -4/3 Energy dominated: E ~ r 3 v 2 K ~ 22 keV cm 2 E 59 3 -5/3 r 10 -4/3 Bubble dominated: E ~ V bub |dP/dr| r K ~ 6 keV cm 2 E 59 3 -5/3 (r/r inj ) -0.18 r 10 -4/3
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Chandra Entropy Profiles Core entropy profiles very regular Entropy inversions are minor and lie at r < 10 kpc
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Beyond the Core ( r 2 ~ const) Sustained Luminosity: L ~ r 2 v 3 v ~ 1600 km s -1 L 46 1/3 (T/5 keV) -1/3 K / K ~ 0.4 L 46 2/3 (T/5 keV) -5/3
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Beyond the Core ( r 2 ~ const) Sustained Luminosity: L ~ r 2 v 3 v ~ 1600 km s -1 L 46 1/3 (T/5 keV) -1/3 K / K ~ 0.4 L 46 2/3 (T/5 keV) -5/3 Preserves shape of original K profile!
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Entropy Profiles Cooling: Breaks self-similarity Its entropy scale determines M-T, L-T relations Feedback: Prevents overcooling What elevates entropy at large radius? Core Profiles: Suggest AGN heating (~10 45 erg s -1, ~10 8 yr) Extended outburst can elevate entire profile
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AGN heating? Yes! AGN are almost certainly the primary stabilizing mechanisms for cooling cores at z~0.
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Next Work Complete entropy profile extraction on other radio quiet clusters (almost done). Test idea that cooling rates ~ star formation rates with RGS and Astro E-2 spectra (faint Fe XVII and O VII lines should be present.) Test deprojection assumptions with realistic hydro simulations.
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Conclusions Recent ICM abundance measurements show enrichment throughout the cluster. ICM abundance evolution since z~1.3 slow; consistent with supernova rates. Central entropies of nearby clusters with short central cooling times are higher in clusters without radio sources. Cooling and star formation explain the ICM L- T relation (at least at high T). AGN are required to complete the story to regulate star formation in cDs and stabilize cool core clusters.
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