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September 1, 2013 by H.E.S.S. Collaboration
Source of the Month

HESS J1640−465 – an exceptionally luminous TeV gamma-ray supernova remnant

HESS J1640−465 – an exceptionally luminous TeV gamma-ray supernova remnant
September 1, 2013 by H.E.S.S. Collaboration
Source of the Month

September 2013

fig0

Composite image showing radio continuum emission at 610 MHz (in blue) from the region around HESS J1640-465 / SNR G338.3−0.0, and infrared emission at 8 μm (in green) and at 24 μm (in red) taken from the Spitzer Space Telescope GLIMPSE and MIPSGAL surveys, respectively. The white circle marks the position and extension of HESS J1640−465, while the cross indicates the location of the extended X-ray source (Lemiere et al. 2009). From Castelletti et al. (2011).

The very high energy (VHE) gamma-ray source HESS J1640−465 (SOM March 2007) was discovered by H.E.S.S. in the Galactic Plane Survey (Aharonian et al. 2006) and is positionally coincident with the supernova remnant (SNR) G338.3−0.0 (see top image). Using XMM-Newton observations Funk et al. (2007) detected an extended X-ray source (XMMU J164045.4−463131) close to the geometric centre of the SNR and within the H.E.S.S. source. The X-ray and VHE gamma-ray emission components were initially interpreted as radiation by relativistic electrons in a pulsar wind nebula (PWN). Observations with Chandra confirmed the presence of the extended X-ray nebula and identified a point-like source which was suggested to be the associated pulsar (Lemiere et al. 2009). Fermi-LAT data revealed a high-energy gamma-ray source coincident with HESS J1640−465 (Slane et al. 2010). The distance to the remnant G338.3−0.0 is estimated to about 10 kpc; radio line emission indicates rather high gas density in the shell, of up to 600 atoms per cm^3.

Since its original discovery, the available H.E.S.S. exposure towards HESS J1640−465 has quadrupled and advanced analysis methods are now available that allow for a much more detailed spectral and morphological study of the VHE gamma-ray emission. Fig. 1 shows the new gamma-ray image of HESS J1640-465. The VHE gamma-ray source encloses the northern part of the SNR shell of G338.3−0.0, the candidate pulsar wind nebula and the Fermi source. The intrinsic size of the H.E.S.S. gamma-ray source is about 4′. Fig. 2 shows the emission spectrum of the source, from radio to VHE gamma rays. Given the now available multi-wavelength data, it turns out that the hypothesis of a pulsar-wind origin of the gamma-ray emission is difficult to maintain; size and spectra (Fig. 2) of the source favor emission caused by interaction of supernova-accelerated cosmic rays with the dense ambient gas, in particular in the northern section of the remnant (Fig. 3). With a distance of ~10 kpc, the high gamma ray flux makes HESS J1640-465 the galactic remnant most luminous in very high energy gamma rays, with a TeV luminosity of about 5×10^35 ergs/s, and an energy of a few 10^51 ergs estimated in accelerated cosmic rays.

Reference: H.E.S.S. Collaboration, A. Abramoswki et al., “HESS J1640−465 – an exceptionally luminous TeV gamma-ray SNR”, to be submitted

fig1

Fig. 1: Gamma ray map of the HESS J1640-465 region. 610 MHz radio contours are shown in black ( Castelletti et al. 2011). The green circle indicates the position of the candidate pulsar wind nebula XMMU J164045.4−463131, and in gray the best fit position of the Fermi source 2FGL 1640.5−4633 is given. The white circle indicates the source HESS J1641−463 (SOM Oct. 2012)

fig2

Fig. 2: Spectral energy distribution of HESS J1640-465 based on H.E.S.S. very high energy gamma ray data, Fermi high energy gamma ray data (Slane et al. 2010), X-ray (Lemiere et al. 2009) and radio data ( Castelletti et al. 2011). Dashed blue and red curves show synchrotron and Inverse Compton emission from non-thermal electrons, respectively, whereas the solid black curve models hadronic gamma-ray emission from decay of neutral pions produced in interactions of accelerated cosmic rays with ambient gas.

fig3

Fig. 3: Spitzer MIPS 24μm infrared image with overlaid contours from the smoothed H.E.S.S. excess map (white). The infrared emission essentially traces the abundance of interstellar dust and dense HII star-forming regions.

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Sources of the month

Each month a TeV gamma ray source investigated with the H.E.S.S. telescopes is featured. See also the pages on Astrophysics with H.E.S.S.: The Nonthermal Universe with an overview of the physics and the source types.

More sources

The Vela Pulsar – the most Highly Energetic ClockNovember 1, 2023
HESS J1645−455 – A gem on the ring?October 1, 2023
The identity crisis of the blazar PKS 1510-089August 1, 2023

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Sources of the month

The Vela Pulsar – the most Highly Energetic ClockNovember 1, 2023
HESS J1645−455 – A gem on the ring?October 1, 2023
The identity crisis of the blazar PKS 1510-089August 1, 2023
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Last sources of the month

The Vela Pulsar – the most Highly Energetic ClockNovember 1, 2023
HESS J1645−455 – A gem on the ring?October 1, 2023
The identity crisis of the blazar PKS 1510-089August 1, 2023

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