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A multi-wavelength view of the pulsar environments

Published online by Cambridge University Press:  04 June 2018

Roberta Zanin
Roberta Zanin*
Affiliation:
Max Planck Institut fur Kernphysik, Saupfercheckweg 1, 69117 Heidelberg, Germany email: robertazanin@gmail.com
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Abstract

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Sometimes the explosion of a supernova can generate a pulsar, most of whose rotational energy is carried away by an energetic wind of particles and magnetic fields expanding into its surroundings and eventually forming extended nebulae, i.e. the pulsar wind nebulae. The experimental advances reached in the last decades, from radio frequencies up to the highest gamma-ray energies, with instruments like VLA, VLBA, Chandra, NuStar, Fermi-LAT and H.E.S.S. among the others, led to the discovery of hundreds of this kind of sources allowing for population studies. In addition, this variety of high-precision spectral and morphological measurement provided an unprecedented opportunity to test and push forward the state-of-the-art theoretical models. In this contribution, we will review the latest, and most significant theoretical and experimental results.

Keywords

PWNSNRpulsar winds
Type
Contributed Papers
Information
Proceedings of the International Astronomical Union , Volume 13 , Symposium S337: Pulsar Astrophysics the Next Fifty Years , September 2017 , pp. 241 - 246
Copyright
Copyright © International Astronomical Union 2018 

References

Arzoumanian, Z., Chernoff, D. F., & Cordes, J. M., 2002, ApJ, 568, 289CrossRefGoogle Scholar
Bandiera, R., Neri, R. & Cesaroni, R., 2002 A&A, 386, 1044Google Scholar
Bandiera, R., 2008 A&A, 490, L3Google Scholar
Begelman, M. C., 1998 ApJ, 493, 291CrossRefGoogle Scholar
Bietenholz, M. F. et al., 1997, ApJ, 490, 291CrossRefGoogle Scholar
Bietenholz, M. F. et al., 2004, ApJ, 615, 794CrossRefGoogle Scholar
Bietenholz, M. F. et al., 2015, MNRAS, 454, 2416CrossRefGoogle Scholar
Blondin, J. M., Chevalier, R., & Frierson, D.M., 2001 ApJ, 563, 806CrossRefGoogle Scholar
Bock, D.C.J., & Gaensler, B.M., 2005 MNRAS, 626, 343Google Scholar
Bogovalov, S. et al., 2005 MNRAS, 358, 750CrossRefGoogle Scholar
Brownsberger, S., & Romani, R., 2014 ApJ, 784, 154CrossRefGoogle Scholar
Bucciantini, N. et al., 2005 A&A, 443, 519Google Scholar
Buelher, R. & Blandford, R., 2014 Reports on Progress in Physics, 77, 6Google Scholar
Caraveo, P. et al., 2003 Science, 301, 1345CrossRefGoogle Scholar
Cerutti, B. et al., 2013 ApJ, 770, 147CrossRefGoogle Scholar
Del Zanna, L. et al., 2004 A&A, 421, 1063Google Scholar
Del Zanna, L. et al., 2006 A&A, 453, 621Google Scholar
Dolch, T. et al., 2016 Journal of Astronomy and Space Sciences, 33, 167CrossRefGoogle Scholar
Donath, A. for the H.E.S.S. collaboration, 2016 Proceedings of the Gamma2016Google Scholar
Fermi-LAT collaboration, 2011, Science, 331, 739CrossRefGoogle Scholar
Gaensler, B. & Slane, P., 2006 ARAA, 44, 17CrossRefGoogle Scholar
Gelfand, J.D. et al., 2009 ApJ, 703, 2051-2067CrossRefGoogle Scholar
H.E.S.S. collaboration, 2006 A&A, 460, 365Google Scholar
H.E.S.S. collaboration, 2012a A&A, 548, 38Google Scholar
H.E.S.S. collaboration, 2012b A & A, 548, 46CrossRefGoogle Scholar
H.E.S.S. collaboration, 2017 accepted by A&A, arXiv:1702.08280Google Scholar
Hester, J. et al., 1996 ApJ, 456, 225CrossRefGoogle Scholar
Hinton, J. et al., 2011 ApJL, 743, L7CrossRefGoogle Scholar
Holler, M. for the H.E.S.S. collaboration, 2017 Proceedings of the 35th ICRC, id.Google Scholar
Kargaltsev, S. et al., 2015 Space Sci. Revs, 191, 391CrossRefGoogle Scholar
Kargaltsev, S. et al., 2017 accepted by Journal of Plasma Physics, 1708.00456Google Scholar
Klinger, N. et al., 2016 ApJ, 828, 70CrossRefGoogle Scholar
Komissarov, S. & Lyubarsky, 2004 MNRAS, 349, 779CrossRefGoogle Scholar
Kothes, R., 2017Google Scholar
Lyutikov, M. et al., submitted to Journal of Plasma Physics, arXiv:1603.05731Google Scholar
Madsen, K. et al., 2015 ApJ, 801, 44CrossRefGoogle Scholar
MAGIC collaboration, 2015 Journal of High Energy Astrophysics, 5, 30Google Scholar
Meyer, M., Horns, D. & Zechlin, H. S., 2010 MNRAS, 523, A2Google Scholar
Martin, J., Torres, D. & Rea, N., 2012 MNRAS, 427, 415CrossRefGoogle Scholar
Mitchell, A. for the H.E.S.S. collaboration, 2017 Proceedings of the 35th ICRC, id.Google Scholar
Olmi, B. et al., 2014 MNRAS, 438, 1518CrossRefGoogle Scholar
Olmi, B. et al., 2015 MNRAS, 449, 3149CrossRefGoogle Scholar
Olmi, B. et al., 2016 Journal of Plasma Physics, 82, 6CrossRefGoogle Scholar
Pavan, L. et al., 2016 A&A, 591, A91Google Scholar
Porth, O. et al., 2013 MNRAS, 431, L48CrossRefGoogle Scholar
Porth, O. et al., 2014 MNRAS, 4 38, 278Google Scholar
Porth, O. et al., 2016 MNRAS, 460, 4135CrossRefGoogle Scholar
Posselt, B. et al., 2016 ApJ, 835, 66CrossRefGoogle Scholar
Reich, W. et al., 1998 A&A Supplement, 131, 11Google Scholar
Reynolds, S. et al., 2017 Space Sci. Revs, 207, 1CrossRefGoogle Scholar
Rudy, A. et al., 2015 The Astrophys. Journal, 811, 24CrossRefGoogle Scholar
Salesa, F. for the HAWC collaboration, 2017 Proceedings of the 35th ICRC, id.Google Scholar
Schweizer, T. et al., 2013 MNRAS, 433, 3325CrossRefGoogle Scholar
Scargle, J., 1969 ApJ, 156, 401CrossRefGoogle Scholar
Sironi, L. & Spitkovosky, A., 2009 ApJ, 698, 1523CrossRefGoogle Scholar
Sironi, L. et al., 2011 ApJ, 741, 39CrossRefGoogle Scholar
Tang, X. & Chevalier, R.E., 2012 ApJ, 752, 83CrossRefGoogle Scholar
Tavani, M. et al., 2011, Science, 331, 736.CrossRefGoogle Scholar
Temim, T. et al., 2006 ApJ, 132, 1610CrossRefGoogle Scholar
Temim, T. et al., 2015 ApJ, 799, 158CrossRefGoogle Scholar
Tibaldo, L. for the H.E.S.S. collaboration, 2017 Proceedings of the 35th ICRC, id.Google Scholar
Torres, D. et al., 2014 Journal of High Energy Astrophysics, 1, 31Google Scholar
Tsirou, M. for the H.E.S.S. collaboration, 2017 Proceedings of the 35th ICRC, id.Google Scholar
van der Swaluw, E. et al., 2001 A&A, 380, 309Google Scholar
van Etten, A. & Romani, R., 2011 ApJ, 742, 62CrossRefGoogle Scholar
Volpi, D. et al., 2008 A&A, 485, 337Google Scholar
Weisskopf, M. et al., 2000, ApJ, 536, L81CrossRefGoogle Scholar
Weisskopf, M. et al., 2013 ApJ, 765, 56CrossRefGoogle Scholar