Shock heating in the group atmosphere of the radio galaxy B2 0838+32A

Shock heating in the group atmosphere of the radio galaxy B2 0838+32A Nazirah Jetha1, Martin Hardcastle2, Trevor Ponman3, Irini Sakelliou4 1 IRFU, CEA-Saclay, 2University of Hertfordshire, 3University of Birmingham, 4MPIA-Heidelberg, Germany Radio galaxies in the Chandra Era, Boston, July 2008

RL RQ XMM RGs Croston et al. 2008 MNRAS 386 1709 Radio Galaxy Heating • Two major unresolved problems: • Similarity breaking -- groups and clusters follow scaling relations, but different from self-similar predictions. • Lack of very cold gas in group and galaxy cores • Increasing evidence that radio galaxies can heat IGM Radio galaxies in the Chandra Era, Boston, July 2008

Radio Galaxy Heating • On small scales, radio galaxies can heat via shocks generated by overpressured rapidly expanding lobes, e.g. Cen. A (Kraft et al 2003), NGC 3801 (Croston et al 2007). • As radio source evolves, heat is transferred in different ways (Reynolds et al, 2002; Kraft et al, 2003; Nusser et al, 2006 ) • Evidence to suggest that repeated cycles of radio galaxy heating have a significant effect (Croston et al, 2005; Jetha et al, 2007). Radio galaxies in the Chandra Era, Boston, July 2008

Radio Galaxy Heating • In order to explore effects of multiple cycles, wantsystems where more than one outburst can be studied simultaneously • And ideally want systems: • Showing the ‘extremes’ of the AGN cycle • Sufficiently distant to study large scale IGM • Close enough to study small-scale shocks • ‘Simple’ enough that effects of multiple outbursts can be disentangled. Radio galaxies in the Chandra Era, Boston, July 2008

2.5 kpc 80kpc 1.4 GHz. (Jetha et al sub.) 0838+032 - Radio • 85 ks Chandra observation to: • Investigate potential shocks around small scale source. • Examine effects of heating on large scale environment. Radio galaxies in the Chandra Era, Boston, July 2008

Host galaxy Companion galaxy Shock Companion galaxy 0838+032 - X-ray • SDSS OPTICAL • 5 GHz VLA • Chandra X-ray Radio galaxies in the Chandra Era, Boston, July 2008

0838+032 - X-ray • Group emission out to ~130 kpc • Shock temperature: • Mach number: 100 Counts arcsec-2 0.12 130 Radius (kpc) Radio galaxies in the Chandra Era, Boston, July 2008

Timescales of the source • Radius of inner lobes - 4.3 kpc • Speed of sound in group - 330 km s-1 • Age - 3.4 - 6.5 Myr • Spectral age of outer lobes ~50 Myr • Dynamic age, assuming lobes inflated in situ - 200 Myr • Infer old lobes switched off ~150 Myr ago Radio galaxies in the Chandra Era, Boston, July 2008

Feedback induced shocks? • Central cooling time of gas - 170 Myr • Comparable to time between old outburst switching off and new outburst switching on • No indication in AGN spectrum for absorption from cold material to suggest merger (c.f. Cen. A, Kraft et al 2006; NGC 3801, Croston et al 2007) Radio galaxies in the Chandra Era, Boston, July 2008

Energetics of inner lobes • Mechanical power output of new source - (5.4 - 62) x 1037 W • No evidence for cold gas, so assume that AGN is accreting in hot-mode. • Calculate Bondi power - PBONDI ~ 6 x 1037 W • Lower limit due to constraints on black hole mass and measuring density at Bondi radius. Radio galaxies in the Chandra Era, Boston, July 2008

Energetics of outer lobes • NW lobe is 130 kpc and S lobe is 190 kpc from centre • Model lobes as ellipsoids with negligible initial volume inflated in situ • Obtain pressure from density profile • PdV work done on IGM - (2 - 4)x1051 J • Mean energy input rate - 3x1035 - 3x1036 W • Bolometric X-ray luminosity (3.2±0.2)x1035 W Radio galaxies in the Chandra Era, Boston, July 2008

Implications for feedback models (1) • Sufficient energy to counteract cooling • Observations of lobes indicate delay in turning off cooling • Due to time for energy/entropy to transfer to where needed • Or time to drain accretion flow: Radio galaxies in the Chandra Era, Boston, July 2008

Implications for feedback models (2) • What about to turn accretion on again? • Central gas cooling time and time between outbursts is comparable • Time taken for gas to cool may determine off time • Clear that relationship between the two timescales determines duty cycles and on-times for any given system Radio galaxies in the Chandra Era, Boston, July 2008

Conclusions • 0838+32A - restarting radio source driving overpressured bubbles into IGM • Old lobes have done sufficient work to counteract radiative cooling • Young lobes driving a shock into IGM • No evidence for merger to trigger new lobes • Time delay in stopping accretion related to energy transfer/flow draining and microphysics of system • First known system where strong shocks around young lobes are plausibly driven by hot-gas accretion (feedback) Radio galaxies in the Chandra Era, Boston, July 2008

Shock heating in the group atmosphere of the radio galaxy B2 0838+32A

Shock heating in the group atmosphere of the radio galaxy B2 0838+32A

Presentation Transcript

The Physiology of Shock

Heating the Atmosphere

Chapter 11 Heating the Atmosphere

The B2 Buzz

Heating the Atmosphere

in the Atmosphere

17.2 – Heating the atmosphere – Part I

The Effects of the Atmosphere and Weather on Radio Astronomy Observations

Earth Science 17.2 Heating the Atmosphere

Earth Science 17.2 Heating the Atmosphere

in the Atmosphere

Heating the Atmosphere

Heating of the Atmosphere

The Effects of the Atmosphere and Weather on Radio Astronomy Observations

AGN Heating of the Intergalactic Medium in Galaxy Groups

Shock heating by galaxy-scale radio sources

Radio sources in the 2dF Galaxy Redshift Survey (2dFGRS)

Heating the Atmosphere Radiation Conduction

ATMOSPHERE HEATING RATE: CLOUD FREE ATMOSPHERE

Gamma Rays from the Radio Galaxy M87

Lecture 6: Heating of Upper Atmosphere

Galaxy Group - Galaxy Vega