[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.5303/JKAS.2015.48.2.155

RADIO EMISSION FROM WEAK SPHERICAL SHOCKS IN THE OUTSKIRTS OF GALAXY CLUSTERS

Kang, Hyesung (Department of Earth Sciences, Pusan National University)

Publication Information

Journal of The Korean Astronomical Society / v.48, no.2, 2015 , pp. 155-164 More about this Journal

Abstract

In Kang (2015) we calculated the acceleration of cosmic-ray electrons at weak spherical shocks that are expected to form in the cluster outskirts, and estimated the diffuse synchrotron radiation emitted by those electrons. There we demonstrated that, at decelerating spherical shocks, the volume integrated spectra of both electrons and radiation deviate significantly from the test-particle power-laws predicted for constant planar shocks, because the shock compression ratio and the flux of inject electrons decrease in time. In this study, we consider spherical blast waves propagating through a constant density core surrounded by an isothermal halo with ρ ∝ r⁻ⁿ in order to explore how the deceleration of the shock affects the radio emission from accelerated electrons. The surface brightness profile and the volumeintegrated radio spectrum of the model shocks are calculated by assuming a ribbon-like shock surface on a spherical shell and the associated downstream region of relativistic electrons. If the postshock magnetic field strength is about 0.7 or 7 µG, at the shock age of ∼ 50 Myr, the volume-integrated radio spectrum steepens gradually with the spectral index from α_inj to α_inj + 0.5 over 0.1–10 GHz, where α_inj is the injection index at the shock position expected from the diffusive shock acceleration theory. Such gradual steepening could explain the curved radio spectrum of the radio relic in cluster A2266, which was interpreted as a broken power-law by Trasatti et al. (2015), if the relic shock is young enough so that the break frequency is around 1 GHz.

Keywords

acceleration of particles; cosmic rays; galaxies: clusters: general; shock waves;

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Times Cited By KSCI : 1 (Citation Analysis)

Reference
Cited By KSCI

1	Bell, A. R. 2004, Turbulent Amplification of Magnetic Field and Diffusive Shock Acceleration of Cosmic Rays, MNRAS, 353, 550 DOI ScienceOn
2	Brüggen, M., Bykov, A., Ryu, D., & Röttgering, H. 2012, Magnetic Fields, Relativistic Particles, and Shock Waves in Cluster Outskirts Space Sci. Rev., 166, 187 DOI
3	Brunetti, G., & Jones, T. W. 2014, Cosmic Rays in Galaxy Clusters and Their Nonthermal Emission, Int. J. of Modern Physics D, 23, 30007
4	Caprioli, D., & Sptikovsky, A. 2014, Simulations of Ion Acceleration at Non-relativistic Shocks. II. Magnetic Field Amplification, ApJ, 794, 46 DOI
5	Drury, L. O’C. 1983, An Introduction to the Theory of Diffusive Shock Acceleration of Energetic Particles in Tenuous Plasmas, Rept. Prog. Phys., 46, 973 DOI ScienceOn
6	Feretti, L., Giovannini, G., Govoni, F., & Murgia, M. 2012, Clusters of Galaxies: Observational Properties of the Diffuse Radio Emission, A&A Rev., 20, 54
7	Kang, H. 2011, Energy Spectrum of Nonthermal Electrons Accelerated at a Plane Shock, JKAS, 44, 49
8	Kang, H., Ryu, D., Cen, R., & Ostriker, J. P. 2007, Cosmological Shock Waves in the Large-Scale Structure of the Universe: Nongravitational Effects, ApJ, 669, 729 DOI
9	Kang, H. 2015, Nonthermal Radiation from Relativistic Electrons Accelerated at Spherically Expanding Shocks, JKAS, 48, 9
10	Kang, H., & Jones, T. W. 2006, Numerical Studies of Diffusive Shock Acceleration at Spherical Shocks, Astropart. Phys., 25, 246 DOI ScienceOn
11	Kang, H., Jones, T. W., & Gieseler, U. D. J. 2002, Numerical Studies of Cosmic-Ray Injection and Acceleration, ApJ, 579, 337 DOI
12	Kang, H., Ryu, D., & Jones, T. W. 2012, Diffusive Shock Acceleration Simulations of Radio Relics, ApJ, 756, 97 DOI
13	Lucek, S. G., & Bell, A. R. 2000, Non-Linear Amplification of a Magnetic Field Driven by Cosmic Ray Streaming, MNRAS, 314, 65 DOI ScienceOn
14	Malkov M. A., & Drury, L. O’C. 2001, Nonlinear Theory of Diffusive Acceleration of Particles by Shock Waves, Rep. Progr. Phys., 64, 429 DOI ScienceOn
15	Nuza, S. E., Hoeft, M., van Weeren, R. J., Gottlöber, S., & Yepes, G. 2012, How Many Radio Relics Await Discovery?, MNRAS, 420, 2006 DOI ScienceOn
16	Ryu, D., Kang, H., Hallman, E., & Jones, T. W. 2003, Cosmological Shock Waves and Their Role in the Large-Scale Structure of the Universe, ApJ, 593, 599 DOI
17	Sarazin, C. L. 1988, X-Ray Emission from Clusters of Galaxies (Cambridge: Cambridge University Press)
18	Schlickeiser, R. 2002, Cosmic Ray Astrophysics (Berlin: Springer)
19	Trasatti, M., Akamatsu, H., Lovisari, L., Klein, U., Bonafede, A., Brggen, M., Dallacasa, D., & Clarke, T. 2015, The Radio Relic in Abell 2256: Overall Spectrum and Implications for Electron Acceleration, A&Ap, 575, A45
20	Shimwell, T. W., Markevitch, M., Brown, S., Feretti, L, et al. 2015, Another Shock for the Bullet Cluster, and the Source of Seed Electrons for Radio Relics, MNRAS, 449, 1486 DOI
21	Skilling, J. 1975, Cosmic Ray Streaming. I - Effect of Alfv´en Waves on Particles, MNRAS, 172, 557 DOI
22	Skillman, S. W., Hallman, E. J., O’Shea, W., Burns, J. O., Smith, B. D., & Turk, M. J. 2011, Galaxy Cluster Radio Relics in Adaptive Mesh Refinement Cosmological Simulations: Relic Properties and Scaling Relationships, ApJ, 735, 96 DOI
23	Stroe, A., Harwood, J. J., Hardcastle, M. J., & Rttgering, H. J. A. 2014, Spectral Age Modelling of the ‘Sausage’ Cluster Radio Relic, MNRAS, 455, 1213
24	van Weeren, R., Röttgering, H. J. A., Brüggen, M., & Hoeft, M. 2010, Particle Acceleration on Megaparsec Scales in a Merging Galaxy Cluster, Science, 330, 347 DOI ScienceOn
25	van Weeren, R., Hoeft, M., Röttgering, H. J. A., Brüggen, M., Intema, H. T., & van Velzen, S. 2011, A Double Radio Relic in the Merging Galaxy Cluster ZwCl 0008.8+5215, A&AP, 528, A38
26	Vazza, F., Brunetti, G., & Gheller, C. 2009, Shock Waves in Eulerian Cosmological Simulations: Main Properties and Acceleration of Cosmic Rays, MNRAS, 395, 1333 DOI ScienceOn
27	Vazza, F., Bruggen, M., Gheller, C., & Brunetti, G., 2012, Modelling Injection and Feedback of Cosmic Rays in Grid-Based Cosmological Simulations: Effects on Cluster Outskirts, MNRAS, 421, 3375 DOI ScienceOn
28	van Weeren, R., Röttgering, H. J. A., Intema, H. T., Rudnick, L., Brüggen, M., Hoeft, M., & Oonk, J. B. R. 2012, The “Toothbrush-Relic”: Evidence for a Coherent Linear 2-Mpc Scale Shock Wave in a Massive Merging Galaxy Cluster?, A&AP, 546, 124 DOI
29	Bell, A. R. 1978, The Acceleration of Cosmic Rays in Shock Fronts. I, MNRAS, 182, 147 DOI

	H. Akamatsu. (2015) Astronomy & Astrophysics SuzakuX-ray study of the double radio relic galaxy cluster CIZA J2242.8+5301 / 582 , A87
1	Hyesung Kang. (2017) The Astrophysical Journal Shock Acceleration Model for the Toothbrush Radio Relic / 840 (1) , 42
1	Sungwook E. Hong. (2015) The Astrophysical Journal RADIO AND X-RAY SHOCKS IN CLUSTERS OF GALAXIES / 812 (1) , 49
2	R. J. van Weeren. (2016) The Astrophysical Journal LOFAR, VLA, ANDCHANDRAOBSERVATIONS OF THE TOOTHBRUSH GALAXY CLUSTER / 818 (2) , 204
1	D. N. Hoang. (2017) Monthly Notices of the Royal Astronomical Society Deep LOFAR observations of the merging galaxy cluster CIZA J2242.8+5301 / 471 (1) , 1107
1	(2019) Space Science Reviews Diffuse Radio Emission from Galaxy Clusters / 215 (1)