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VERITAS Observations of Supernova Remnants. Reshmi Mukherjee 1 for the VERITAS Collaboration 1 Barnard College, Columbia University. Chandra SNR Meeting, Boston, Jul 8, 2009. Outline. (Quick) introduction to VERITAS Scientific goals & questions Observing program VERITAS -ray results.
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VERITAS Observations of Supernova Remnants • Reshmi Mukherjee1 for the VERITAS Collaboration • 1Barnard College, Columbia University Chandra SNR Meeting, Boston, Jul 8, 2009
Outline • (Quick) introduction to VERITAS • Scientific goals & questions • Observing program • VERITAS -ray results
VERITAS at Whipple Observatory Since March 2006 T2 109 m Fall 2006 85 m T3 82 m 35 m T4 T1 April 2007 • Instrument design: • Four 12-m telescopes • 499-pixel cameras (3.5° FoV) • FLWO,Mt. Hopkins, Az (1268 m) • Completed Spring, 2007
VERITAS: The Atmospheric Cherenkov Technique g-ray camera ns electronics Cherenkov image Area = 104 – 105 m2 ~60 optical photons/m2/TeV Imaging ACTs use the shape and orientation of the air shower image in the camera plane to distinguish between cosmic & -rays.
VERITAS Sensitivity • Sensitive energy range: 100 GeV to > 30 TeV • Spectral reconstruction begins at ~150GeV • Energy resolution: ~15% - 20% • Peak effective area: 100,000 m2 • Angular resolution: 0.1o at 1 TeV, 0.14o at 200 GeV (68% values) • 1% Crab detection (5s) in less than 50 h, 5% crab in ~2.5 h • Observation time per year: 750 h non-moonlight, 100 h moonlight
Galactic Science Program • VERITAS Key Science Project • Supernova remnants/PWNe • Non-thermal shells • Shell-molecular cloud interactions • TeVPWNe associated with high E/d2 pulsars Goal of KSP: Constraints on particle acceleration and diffusion. Cosmic ray origin? Measurement of TeV emission from SNRs could resolve the long-standing question of whether these are sites of hadronic cosmic ray acceleration. Is there clear evidence of hadronic emission? Is the TeV IC emission low? Can we demonstrate a robust correlation of TeV emission with target matter? Combining the TeV spectrum with the synchrotron spectra in the radio and X-ray bands can possibly discriminate between IC and pion production/decay models, and provide strong constraints on the acceleration process.
VERITAS Observations of SNRs • Supernova remnants are widely considered to be the strongest candidate for the source of cosmic rays below the knee at around 1015 eV. • Several SNRs have been detected at TeV energies. • Here we present results on: • Cas A • IC 443 • W 44 TeVCat:://tevcat.uchicago.edu/
Results: Cas A SNR & PWNe KSP: • Young (330 yr), shell-type SNR at a distance of ~3.4 kpc. • Massive star progenitor • 5’ diameter (~TeV ang resolution). • Discovered in TeV by HEGRA (232 hrs, 5 s), confirmed by MAGIC (47 hrs, 5.3 s) • Flux ~ 3.3 % Crab above 1 TeV • Power-law G: 2.3 ± 0.2stat ± 0.2sys • Extensive modeling of cosmic-ray acceleration and g-ray production exists. Stage et al. 2006 credit: NASA/CXC/SAO/ D.Patnaude et al. Deep Chandra image of Cas A (7.3’ by 6.4’)
Results: Cas A • VERITAS: • - wobble-mode observations, 0.5º offset, during Oct/Nov 2007 with full 4 Tel. array • Exposure: 22 hr: 8.3 s detection • Flux: ~ 3% Crab • Consistent with a point source. Acciari et al. (2009), in prep.
Results: Cas A VERITAS Spectrum G = 2.61 +/- 0.24stat +/- 0.20sys Acciari et al. (2009), in prep. • Well-fit by power law spectrum: dN/dE = N0(E/TeV)-G • Flux (E > 1 TeV): ~ 3.5% Crab (7.76 +/- 1.10stat+/- 1.55sys) X 10-13 cm-2 s-1 • No sign of energy cut-off at high energy
MAGIC + Black – optical White – EGRET Color - CO 3-10 keV X-rays Bocchino & Bykov 2001 Results: IC 443 • Shell interacting with molecular cloud -> potential target material • EGRET emission centered on remnant, overlaps cloud • MAGIC emission centered on cloud • PWN at southern edge of shell • Distance ~ 1.5 kpc • Age ~ 30,000 years • Diameter 45’ • Distinct shell in radio, optical Stage et al. 2006 Compelling reasons to search for TeV emission from IC 443: s from cosmic rays, or from the PWN?
Results: IC 443 • Discovered in TeV in 2007 • by VERITAS (7.1/6.0 s pre/post-trials in 15.9 hrs) • by MAGIC (5.7 s in 29 hrs) • Wobble-mode observations, 0.5º offset • Observed during two epochs: • Feb / Mar 2007 with 3 telescopes • PWN location, CXOU J061705.3+222127 • Oct / Nov 2007 with 4 telescopes • Center of Feb/Mar hot spot: 06 16.9 +22 33 • Total livetime: 37.1 hrs. • Flux ~3% Crab • 8.2σ peak significance pre-trials Acciari et al. ApJL 698 L133 (2009) Stage et al. 2006 • 2-D Gaussian profile fit: • Centroid: 06 16.9 +22 32.4 ± 0.03º(stat) ± 0.07º(syst) • Extension: σ ~ 0.17º ± 0.02º(stat) ± 0.04º(syst)
Results: IC 443 Multiwavelength Picture Acciari et al. ApJL 698 L133 (2009) • Overlap with CO indicating molecular cloud along line of sight • Maser emission suggests SNR shock interacting with cloud • TeV emission could be • CR-induced pion production in cloud • associated with the pulsar wind nebula to the south • GeV and TeV emission spatially separated? Stage et al. 2006
Results: IC 443 Acciari et al. ApJL 698 L133 (2009) Stage et al. 2006 • Power-law fit 0.3 – 2 TeV: G = 2.99 ± 0.38stat ± 0.30sys • Threshold of energy spectrum - 300 GeV • The integral flux above 300 GeV is (4.63 ± 0.90stat ± 0.93sys) X10−12 cm−2 s−1 (3.2% Crab), in good agreement with the spectrum reported by MAGIC
Observations of Other SNRs • CTB 109 (G109.1-1.0): Shell-type SNR, interacting with a molecular cloud on its eastern rim. Observed briefly for 4.3 hrs (live time). No emission detected. Flux UL (E > 400 GeV) < 2.5X10-12 cm-2 s-1 • FVW 190.2+1.1: Forbidden Velocity Wings may be the vestiges of very old SNRs. FVW 190.2+1.1 shows a clear shell-like morphology in the HI maps. Motivated by the possible association of HESS J1503-582 with an FVW. VERITAS observed for 18.4 hrs (live time) No emission detected. Flux UL (E> 500 GeV) < 0.26X10-12 cm-2 s-1 (< 1% Crab nebula flux) • W 44: SNR promising source of p0 induced g-rays. 13 hr live time around W44. No emission detected around SNR. Flux UL (E > 300 GeV) < 2% Crab nebula flux.
Observations of Other SNRs Fig. from Wolsczcan et al. 1991 • W44 is an SNR with large angular extent. • W44 is a bright radio source. • X-ray emission centrally peaked, predominantly thermal X-ray emission • A plerion is visible in radio and X-rays associated with PSR 1853+01 (Harrus 1997). • 0FGL J1855.9+0126 , marginally coincident with PSR 1853+01, has flux ≃ 2.5% of Crab in the energy range (1 − 100)GeV. Contours: Radio emission Shaded area: X-rays
The field of W 44 Unidentified Sources: HESS J1857+026 and HESS J1858+020 • 9.2 hrs livetime on W44 position. 6.4 hrs on UIDs • J1857+026 possibly associated with PWN AX J185651+0245 powered by newly discovered radio pulsar PSR J1856+0245 • W44: UL ~2 % Crab • J1857+026: 5.6 s • J1858+020: not detected • Agreement with HESS: • HESSJ1857+026 is detected in the position reported by HESS. • Morphology of HESS J1857+026 is well reproduced. Acciari et al. in prep
Summary • IC 443: Extended and complicated • Extended emission; soft spectrum • Origin: PWN or SNR/MC interaction? • Strong Fermi source: broadband spectral, morphological evolution will be illuminating • Cas A: • Detection with 8.3s significance in 22hrs • Consistent with a point source • Power-law spectrum up to ~5 TeV; no sign of a cut-off • Well-measured spectrum. Boon to modelers • Other SNRs:Lack of strong (>5% Crab) sources
Future Directions … Upgrade Relocating T1 will improve the sensitivity of VERITAS by ~15% → equivalent of gaining an annual 300 hr extra in obs. time. Impacts all physics goals. New platform for T1 Disassembly of T1
Results: Cas A • The question of whether or not there is a sufficiently high flux of Galactic nuclear CRs resulting in a steady flux of VHE g–rays, remains one of the most stimulating scientific questions of ground-based g –ray astronomy. (Berezhko et al. 2003) • The non-thermal X-ray emission predominantly originates from filaments and knots in the reverse-shock region of Cas A (Helder & Vink 2008). • The presence of a large flux of high-energy electrons in the reverse-shock region, responsible for the non-thermal radio to X-ray emission, will also produce high-energy γ -ray emission through non-thermal bremsstrahlung and IC scattering (Atoyan 2006). • Based on that leptonic emission, Cas A would appear in VERITAS data as a disk or ring-like source with outer radius 2.5′ (Uchiyama & Aharonian 2000). • If, on the other hand, the VHE γ -ray emission from Cas A were dominated by p0 decay produced in inelastic collisions of relativistic protons, the location of the particle-acceleration site is less constrained by data in other wavebands.
Cosmic rays accelerated at expanding shock front electrons and/or nuclei synchrotron radiation observed in radio through X-rays TeV observations constrain Nature of particles Acceleration process Role of SNRs in production of Galactic cosmic rays Growing class: ~8 known or likely SNR associations VERITAS Observations of SNRs IC 443 CTB 109 FVW 190.2+1.1 W44 Cas A Stage et al. 2006
IC 443 • Green – Radio • Red – Optical • Blue – X-rays • Distance ~ 1.5 kpc • Age ~ 30,000 years • Diameter 45’ • Distinct shell in radio, optical • Shell interacting with molecular cloud potential target material • EGRET emission centered on remnant, overlaps cloud • MAGIC emission centered on cloud • PWNat southern edge of shell Stage et al. 2006 Compelling reasons to study TeV emission from IC 443: s from cosmic rays, or from the PWN? Observations of SNRs with VERITAS
VERITAS Galactic Science • In addition … • Cygnus region sky survey (key science) • Compact sources in the Milky Way • TeV observations of X-ray binaries: • Is the compact object BH emitting jet ? • Is it a pulsar with pulsar wind? • Are these systems accreting binaries (microquasars?) Emission mechanisms? • Unidentified Galactic sources • EGRET unidentified sources • TeV unidentified sources • Fermi unidentified sources & transients J. Paredes
VERITAS: Astrophysics at the highest energies Supernova remnants, plerions, unidentified sources: - cosmic ray origin? Constraints on particle acceleration and diffusion. Gamma-Ray Bursts. Active galaxies: Relativistic jets. - shock acceleration? - particle type? Fundamental Physics/ Dark Matter Studies (Neutralino Annihilation). Search for Dark matter in Galactic Center. Minihaloes? Diffuse extragalactic background light • VERITAS will explore astrophysical situations in which physics operates under extreme conditions – (e.g. intense gravitational or magnetic fields.) • Study particle acceleration in extreme astrophysical environments (AGN, GRBs). • Use -rays to probe intergalactic space -- Diffuse radiation fields. • Probe novel astrophysical phenomena which could arise as a result of new physics beyond the standard model of particle interactions.