1 / 16

High Energy Studies of Evolved Pulsar Wind Nebulae

High Energy Studies of Evolved Pulsar Wind Nebulae. Collaborators: D. Castro S. Funk J. Gelfand T. Temim D. Foight J.P. Hughes M. Lemoine-Goumard R. Rousseau B. Gaensler and others…. Evolution of PWN Structure. PWN expands within SNR as it sweeps up ejecta

cosima
Download Presentation

High Energy Studies of Evolved Pulsar Wind Nebulae

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. High Energy Studies of Evolved Pulsar Wind Nebulae Collaborators: D. Castro S. Funk J. Gelfand T. Temim D. Foight J.P. Hughes M. Lemoine-Goumard R. Rousseau B. Gaensler and others…

  2. Evolution of PWN Structure • PWN expands within SNR as it • sweeps up ejecta • - eventually, SNR reverse shock • reaches PWN and halts expansion • X-ray observations provide • ambient density estimates • - connect to age, energetics • Magnetic field in PWN decreases • dramatically during adiabatic • expansion • Upon RS interaction, PWN is • compressed and magnetic field • is increased • - high energy particles burn off • rapidly • - PWN is disrupted, often dramatically CMB inverse Compton synchrotron

  3. Evolution of PWN Emission Spitkovsky 2008 1000 yr 2000 yr 5000 yr • Injected spectrum is expected to be • Maxwellian w/ nonthermal tail • - note that Maxwellian has never been • definitively detected • Emax and fraction of energy in PL • likely to vary within PWN • Energetic electrons produce synchrotron • emission in X-ray band, and IC emission • in g-ray band • Note that X-ray emission decreases • with time, while g-ray emission increases CMB inverse Compton synchrotron

  4. From Young to Old

  5. HESS J1640-465 Slane et al. 2010 • Composite SNR in late evolution • PWN model with evolved power • law electron spectrum fits X-ray • and TeV emission, but not GeV

  6. HESS J1640-465 Slane et al. 2010 • Composite SNR in late evolution • PWN model with evolved power • law electron spectrum fits X-ray • and TeV emission, but not GeV • Modifying low-energy electron • spectrum by adding Maxwellian • produces GeV IC emission • similar to results from Vela X • possible evidence of long-sought • Maxwellian component expected from • shock acceleration models

  7. MSH 11-62 • Radio observations reveal shell with • bright, flat-spectrum nebula in center • - no pulsar known, but surely a PWN • Distance not well known, but ≈5 kpc • - R ≈ 10.6 pc

  8. MSH 11-62 CXO • X-ray spectrum gives n0 ≈ 0.6 cm-3 • SNR/PWN modeling gives t ≈ 5 kyr • - SNR reverse shock has begun to interact • with PWN • X-ray studies show thermal shell with a • central PWN • - pulsar candidate seen as hard point source • in center of PWN (offset from radio center)

  9. MSH 11-62 Fermi LAT • Spectrum well-described by cut-off PL • - Ecut ≈ 5 GeV, consistent w/ pulsar spectra • Pion model gives acceptable fit • - requires n0 = 7 cm-3 and Ecut = 70 GeV • - these values are too high and too low, • respectively, for a typical SNR scenario • 1FGL J1112.1-6041 is spatially associated • with MSH 11-62 • - F(>100 MeV) ≈ 1 x 10-10 erg cm-2 s-1 • Two nearby pulsars w/ Ė > 1033 erg/s • - neither can yield more than 3% of the flux

  10. MSH 11-62 • PWN model with PL injection cannot fit • broadband spectrum • - either over-predicts TeV flux or under- • predicts GeV flux • - similar to Vela X and HESS J1640-465 • Model w/ Maxwellian + PL gives good • approximation to data • - ge ≈ 106, G ≈ 2.7; EPL = 0.01 EMaxwellian • - B ≈ 2 mG, typical of evolved PWN • Fermi observations of MSH 11-62 are • consistent with emission arising from • an evolved PWN • - if correct, broadband modeling appears to • provide additional support for presence of • Maxwellian electron component • - cannot rule out pulsar as origin of GeV • emission • - timing and sub-mm observations important

  11. MSH 15-56 MOST • Prototypical composite SNR • Radio observations reveal shell with • bright, flat-spectrum nebula in center • - no pulsar known, but surely a PWN • - nebula significantly displaced from SNR • center • Kinematic distance ≈4 kpc based on • Ha radial velocity measurements • - R ≈ 20 pc

  12. MSH 15-56 ROSAT CXO • X-ray spectrum gives n0 ≈ 0.1 cm-3 • SNR/PWN modeling gives t ≈ 12 kyr • - SNR reverse shock has completely • disrupted PWN • X-ray studies show thermal shell w/ • very faint hard emission near PWN • - pulsar candidate seen as hard point source • w/ faint X-ray trail extending to PWN

  13. MSH 15-56 Fermi LAT • PL spectrum provides reasonable fit • - any cutoff much harder than for pulsars • Pion model gives acceptable fit • - requires n0 = 1.5 cm-3 and Ecut = 300 GeV • - these values are too high and a bit low, • respectively, for a typical SNR scenario • 1FGL J1552.4-5609 is spatially associated • with MSH 15-56 • - F(> 100 MeV) ≈ 3.3 x 10-10 erg cm-2 s-1 • One nearby pulsar w/ Ė > 1033 erg/s • - can not yield more than 5% of the flux

  14. MSH 15-56 • PWN model with PL injection cannot fit • broadband spectrum • - either over-predicts TeV flux or under- • predicts GeV flux • Broken PL reproduced general behavior, • but misses radio index, X-ray flux, and • TeV upper limit • - low X-ray to radio flux ratio consistent • with post-compression PWN phase • Fermi observations of MSH 15-56 may • be consistent with emission from an • evolved PWN • - if correct, pulsar has essentially departed • relic PWN and is injecting particles into • newly-forming nebula • - additional modeling required to consider • possible evidence for low-energy electron • component

  15. Missing Cousins? G272.2-3.2 • Do other SNRs with ages similar to the • detected composite SNRs also show GeV • emission? • - Certainly not all. Little or no evidence from • G272.2-3.2, Kes 73, or G299.2-2.9 • - no strong evidence of emission from magnetar • in Kes 73 either… • Not exactly a “control sample” • - distance from Galactic Plane is large for • G272.2-3.2 and G299.2-2.9 (density low, • but confusion from Plane also low…) • - small number statistics… • Need to carry out further Fermi studies • to establish whether or not composite • SNRs are more prevalent GeV emitters • (which would point to either PWN or • pulsar as origin of emission d ~ 5 kpc, R ~ 12 pc, t ~ 6-15 kyr Kes 73 d ~ 7.5 kpc, R ~ 4 pc, t ~ 1 kyr G299.2-2.9 d ~ 5 kpc, R ~ 7 pc, t ~ 4.5 kyr

  16. Conclusions • Both X-ray and g-ray emission are produced in composite SNRs • - GeV emission is expected to increase as PWN evolves; X-ray • emission decreases • Broadband modeling places strong constraints on evolution of • composite SNRs • - provide probe of underlying electron spectrum • MSH 11-62 may provide additional evidence of a Maxwellian electron • component accompanying the power law tail • - spectrum could also be produced by pulsar; pulsation searches • and studies of spatial extent needed • - sub-mm observations to confirm or refute presence of Maxwellian • electron distribution are crucial for this and other systems • MSH 15-56 appears to be in late phase of evolution • - GeV emission provides unique probe of evolved electron population • Continued X-ray and g-ray studies of composite SNRs hold promise

More Related