Presentation is loading. Please wait.

Presentation is loading. Please wait.

Cosmic ray acceleration in the MSH 14-63 supernova remnant (RCW 86) Eveline Helder together with: Jacco Vink, Cees Bassa, Aya Bamba,

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "Cosmic ray acceleration in the MSH 14-63 supernova remnant (RCW 86) Eveline Helder together with: Jacco Vink, Cees Bassa, Aya Bamba,"— Presentation transcript:

1 Cosmic ray acceleration in the MSH 14-63 supernova remnant (RCW 86) Eveline Helder (e.a.helder@uu.nl) together with: Jacco Vink, Cees Bassa, Aya Bamba, Johan Bleeker, Stefan Funk, Parviz Ghavamian, Kurt van der Heyden, Frank Verbunt, Ryo Yamazaki

2 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 2/20 Supernova remnants as CR accelerators To maintain energy budget, ~10% of the energy of a SNR needs to go into cosmic rays X-ray synchrotron emission has been detected at shock fronts of several supernova remnants Several remnants have been observed in gamma-rays

3 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 3/20 Imprints of CR acceleration Post-shock compression ratio > 4 (Warren+ 2005, Cassam-Chenaï+ 2008, Miceli+ 2009) Lower post-shock temperature (Hughes+ 2000) from conservation of mass momentum and energy kT = (3/16) mV 2

4 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 4/20 Method Measure velocity and temperature –V: compare 2 images –T: electron temperature contributes only minor part to post-shock pressure, and hard to obtain in spectra dominated by synchrotron emission Ion temperatures hard to measure –done in UV (Raymond+ 1995, Ghavamian+ 2007) –done in X-ray (Vink+ 2003)

5 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 5/20 Use optical spectrum to determine proton temperature: H-lines consist of 2 superimposed peaks: narrow reflects T ISM broad reflects T p (Chevalier+ 1980)

6 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 6/20 RCW 86 Observed in TeV gamma-rays (Aharonian+ 2009) Parts of the rim show X-ray synchrotron emission (Bamba+ 2000, Borkowski+ 2000) Can measure the post-shock proton temperature at location of X-ray synchrotron (Smith 1997)

7 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 7/20 RCW 86 X-ray (Chandra) X-ray (blue) + H  (red)

8 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 8/20 Temperature (H  line) FWHM = 1100 km/s => T p = 2.3 keV

9 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 9/20

10 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 10/20

11 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 11/20 Distance OB association at 2.5 kpc (Westerlund 1969) Local V ISM combined with Galactic rotation curve gives ~2.5 kpc (Rosado+ 1996, Sollerman+ 2003) Blowout seen in CO with same velocity (Matsunaga+ 2001)

12 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 12/20 Numbers Shock velocity is 6000 ± 2800 km/s FWHM broad line 1100 ± 60 km/s This would correspond to a shock velocity of ~ 1100 km/s We observe the effect of cosmic ray acceleration

13 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 13/20 Equations Add term for cosmic ray pressure and energy absorbed by cosmic rays to the conservation laws. Equation of state goes from 5/3 to 4/3 as pressure gets more cosmic ray dominated P CR /P Total F CR /F tot

14 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 14/20

15 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 15/20

16 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 16/20

17 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 17/20

18 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 18/20

19 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 19/20 Conclusions The effect of cosmic ray acceleration on the kinematics of RCW 86 can not be ignored The lower limit to the pressure, contributed by cosmic rays is 50% of the total pressure

20 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 20/20 Future work Include cross sections for charge exchange in calculating proton temperature Measure proper motion using H  images

21 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 21/20 Thank you!

22 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 22/20

23 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 23/20 Other energy sinks? Magnetic pressure? –B 2 /8  ≈ 0.1nkT –B 2 /8  ~ 0.5 V s /c U c (Bell 2004) U c is the cosmic ray energy density Radiative losses? –This particular part of RCW 86 is non radiative (shows no [SII]-lines) (Smith 1997)

24 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 24/20 Proper motion (X-ray imaging) 0.5’’ ± 0.2’’ /yr @ 2.5 kpc => 6000 km/s

25 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 25/20 HH [SII] Smith, 1997

26 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 26/20 Heng+ 2007 Van Adelsberg+ 2008 VsVs VsVs Cross section FWHM

27 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 27/20 Ghavamian+ 2007 Van Adelsberg+ 2008

28 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 28/20 photon + Shock front

29 Cosmic ray acceleration in the RCW86 SNR Boston, July 8 th 2009Eveline Helder Utrecht University 29/20 Cosmic ray acceleration (Spitkovsky 2007)

Download ppt "Cosmic ray acceleration in the MSH 14-63 supernova remnant (RCW 86) Eveline Helder together with: Jacco Vink, Cees Bassa, Aya Bamba,"

Similar presentations

Charge Exchange Models for X-ray Spectroscopy with AtomDB v2.0 Randall Smith, Adam Foster & Nancy Brickhouse Smithsonian Astrophysical Observatory.

Charge Exchange Models for X-ray Spectroscopy with AtomDB v2.0 Randall Smith, Adam Foster & Nancy Brickhouse Smithsonian Astrophysical Observatory.
(2) Profile of the Non-Thermal Filaments of SNRs =>High Energy Particle Acceleration =>High Energy Particle Acceleration In all the SNRs & GC Non Thermal.

(2) Profile of the Non-Thermal Filaments of SNRs =>High Energy Particle Acceleration =>High Energy Particle Acceleration In all the SNRs & GC Non Thermal.
Supernova Remnants Shell-type versus Crab-like Phases of shell-type SNR.

Supernova Remnants Shell-type versus Crab-like Phases of shell-type SNR.
THE ORIGIN OF COSMIC RAYS Implications from and for X and γ-Ray Astronomy Pasquale Blasi INAF/Osservatorio Astrofisico di Arcetri, Firenze.

THE ORIGIN OF COSMIC RAYS Implications from and for X and γ-Ray Astronomy Pasquale Blasi INAF/Osservatorio Astrofisico di Arcetri, Firenze.
Modeling photon and neutrino emission from the supernova remnant RX J1713.7-3946  Constraints from geometry  Constraints from spectral energy distribution.

Modeling photon and neutrino emission from the supernova remnant RX J  Constraints from geometry  Constraints from spectral energy distribution.
1 The Multi-Messenger Approach to Unidentified Gamma-Ray Sources Morphological and spectral studies of the shell-type supernova remnants RX J1713.7-3946.

1 The Multi-Messenger Approach to Unidentified Gamma-Ray Sources Morphological and spectral studies of the shell-type supernova remnants RX J
Diffusive shock acceleration & magnetic field amplification Tony Bell University of Oxford Rutherford Appleton Laboratory SN1006: A supernova remnant 7,000.

Diffusive shock acceleration & magnetic field amplification Tony Bell University of Oxford Rutherford Appleton Laboratory SN1006: A supernova remnant 7,000.
Strange Galactic Supernova Remnants G357.7-0.1 (the Tornado) & G350.1-0.3 in X-rays Anant Tanna Physics IV 2007 Supervisor: Prof. Bryan Gaensler.

Strange Galactic Supernova Remnants G (the Tornado) & G in X-rays Anant Tanna Physics IV 2007 Supervisor: Prof. Bryan Gaensler.
RX J0852.2-4622 alias Vela Jr. The Remnant of the Nearest Historical Supernova : Impacting on the Present Day Climate? Bernd Aschenbach Vaterstetten, Germany.

RX J alias Vela Jr. The Remnant of the Nearest Historical Supernova : Impacting on the Present Day Climate? Bernd Aschenbach Vaterstetten, Germany.
The Fermi Bubbles as a Scaled-up Version of Supernova Remnants and Predictions in the TeV Band YUTAKA FUJITA (OSAKA) RYO YAMAZAKI (AOYAMA) YUTAKA OHIRA.

The Fermi Bubbles as a Scaled-up Version of Supernova Remnants and Predictions in the TeV Band YUTAKA FUJITA (OSAKA) RYO YAMAZAKI (AOYAMA) YUTAKA OHIRA.
2009 July 8 Supernova Remants and Pulsar Wind Nebulae in the Chandra Era 1 Modeling the Dynamical and Radiative Evolution of a Pulsar Wind Nebula inside.

2009 July 8 Supernova Remants and Pulsar Wind Nebulae in the Chandra Era 1 Modeling the Dynamical and Radiative Evolution of a Pulsar Wind Nebula inside.
October 10, 2002COSPAR Houston, TX1 X-Ray Spectral Morphologies of Young Supernova Remnants John P. Hughes Rutgers University  Cara Rakowski, Rutgers.

October 10, 2002COSPAR Houston, TX1 X-Ray Spectral Morphologies of Young Supernova Remnants John P. Hughes Rutgers University  Cara Rakowski, Rutgers.
The Molecular Environment of the SNR HESS J1731-347 (G353.6-0.7) refs: 1503.06717 1405.2599 By: Zhang, Xiao (2015-04-14)

The Molecular Environment of the SNR HESS J (G ) refs: By: Zhang, Xiao ( )
Observational Constraints on Electron Heating at Collisionless Shocks in Supernova Remnants Cara Rakowski NRL J. Martin Laming NRL Parviz Ghavamian STScI.

Observational Constraints on Electron Heating at Collisionless Shocks in Supernova Remnants Cara Rakowski NRL J. Martin Laming NRL Parviz Ghavamian STScI.
High Resolution X-ray Spectroscopy of SN 1006 X-ray Diagnostics of Astrophysical Plasmas Jacco Vink (SRON Nat. Inst. for Space Research) Cambridge Ma,

High Resolution X-ray Spectroscopy of SN 1006 X-ray Diagnostics of Astrophysical Plasmas Jacco Vink (SRON Nat. Inst. for Space Research) Cambridge Ma,
Magnetic-field production by cosmic rays drifting upstream of SNR shocks Martin Pohl, ISU with Tom Stroman, ISU, Jacek Niemiec, PAN.

Magnetic-field production by cosmic rays drifting upstream of SNR shocks Martin Pohl, ISU with Tom Stroman, ISU, Jacek Niemiec, PAN.
Diffuse Gamma-Ray Emission Su Yang 2010.1.19. Telescopes Examples Our work.

Diffuse Gamma-Ray Emission Su Yang Telescopes Examples Our work.
Pasquale Blasi INAF/Arcetri Astrophysical Observatory 4th School on Cosmic Rays and Astrophysics UFABC - Santo André - São Paulo – Brazil.

Pasquale Blasi INAF/Arcetri Astrophysical Observatory 4th School on Cosmic Rays and Astrophysics UFABC - Santo André - São Paulo – Brazil.
Krakow 2008 Damiano Caprioli Scuola Normale Superiore – Pisa, Italy The dynamical effects of self-generated magnetic fields in cosmic-ray-modified shocks.

Krakow 2008 Damiano Caprioli Scuola Normale Superiore – Pisa, Italy The dynamical effects of self-generated magnetic fields in cosmic-ray-modified shocks.
TeV Unidentified Sources Workshop - PSU (4-5 June 2008) Patrick Slane (CfA) High Energy Emission from Supernova Remnants.

TeV Unidentified Sources Workshop - PSU (4-5 June 2008) Patrick Slane (CfA) High Energy Emission from Supernova Remnants.

Similar presentations

Ads by Google