Hard X-ray quiescent emission in magnetars via resonant Compton upscattering
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Date
2017Author
Baring, M.G.
Wadiasingh, Z.
Gonthier, P.L.
Harding, A.K.
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Non-thermal quiescent X-ray emission extending between 10 keV and around 150
keV has been seen in about 10 magnetars by RXTE, INTEGRAL, Suzaku, NuSTAR and Fermi-
GBM. For inner magnetospheric models of such hard X-ray signals, inverse Compton scattering
is anticipated to be the most efficient process for generating the continuum radiation, because
the scattering cross section is resonant at the cyclotron frequency. We present hard X-ray
upscattering spectra for uncooled monoenergetic relativistic electrons injected in inner regions
of pulsar magnetospheres. These model spectra are integrated over bundles of closed field lines
and obtained for different observing perspectives. The spectral turnover energies are critically
dependent on the observer viewing angles and electron Lorentz factor. We find that electrons
with energies less than around 15 MeV will emit most of their radiation below 250 keV, consistent
with the turnovers inferred in magnetar hard X-ray tails. Electrons of higher energy still emit
most of the radiation below around 1 MeV, except for quasi-equatorial emission locales for select
pulse phases. Our spectral computations use a new state-of-the-art, spin-dependent formalism
for the QED Compton scattering cross section in strong magnetic fields
URI
http://hdl.handle.net/10394/26154http://iopscience.iop.org/article/10.1088/1742-6596/932/1/012021/pdf
http://doi.org/10.1088/1742-6596/932/1/012021