MODELING THE MULTI-WAVELENGTH EMISSION OF THE SHELL-TYPE SUPERNOVA REMNANT RX J1713.7-3946

Emission mechanisms of the shell-type supernova remnant (SNR) RX J1713.7--3946 are studied with multi-wavelength observational data from the radio, X-ray, GeV Delta *g-ray, and TeV Delta *g-ray bands. A Markov Chain Monte Carlo method is employed to explore the high-dimensional model parameter space...

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Veröffentlicht in:	The Astrophysical journal 2011-07, Vol.735 (2), p.120-jQuery1323906702161='48'
Hauptverfasser:	QIANG YUAN, SIMING LIU, ZHONGHUI FAN, XIAOJUN BI, FRYER, Christopher L
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Sprache:	eng
Schlagworte:	Astronomy ASTROPHYSICS, COSMOLOGY AND ASTRONOMY CALCULATION METHODS COSMIC RADIATION COSMIC RADIO SOURCES Earth, ocean, space ELECTROMAGNETIC RADIATION EMISSION Exact sciences and technology GAMMA RADIATION IONIZING RADIATIONS MONTE CARLO METHOD RADIATIONS SIMULATION SUPERNOVA REMNANTS
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description	Emission mechanisms of the shell-type supernova remnant (SNR) RX J1713.7--3946 are studied with multi-wavelength observational data from the radio, X-ray, GeV Delta g-ray, and TeV Delta g-ray bands. A Markov Chain Monte Carlo method is employed to explore the high-dimensional model parameter space systematically. Three scenarios for the Delta g-ray emission are investigated: the leptonic, the hadronic, and a hybrid. Thermal emission from the background plasma is also included to constrain the gas density, assuming ionization equilibrium, and a 2 Delta s upper limit of about 0.03 cm--3 is obtained as far as thermal energies account for a significant fraction of the dissipated kinetic energy of the SNR shock. Although systematic errors dominate the Delta y2 of the spectral fit of all models, we find that (1) the leptonic model has the best constrained model parameters, whose values can be easily accommodated with a typical supernova, but gives a relatively poor fit to the TeV Delta g-ray data; (2) the hybrid scenario has one more parameter than the leptonic one and improves the overall spectral fit significantly; and (3) the hadronic one, which has three more parameters than the leptonic model, gives the best fit to the overall spectrum with relatively poorly constrained model parameters and very hard spectra of accelerated particles. The uncertainties of the model parameters decrease significantly if the spectral indices of accelerated electrons and protons are the same. The hybrid and hadronic models also require an energy input into high-energy protons, which seems to be too high compared with typical values for a supernova explosion. Further investigations are required to reconcile these observations with SNR theories.
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title	MODELING THE MULTI-WAVELENGTH EMISSION OF THE SHELL-TYPE SUPERNOVA REMNANT RX J1713.7-3946
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