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Trajectories and Radiation of Charged Particles in the Pulsar Magnetosphere

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arxiv 2204.02072 v1 pith:R6OA7Y4F submitted 2022-04-05 hep-ph astro-ph.HE

Trajectories and Radiation of Charged Particles in the Pulsar Magnetosphere

classification hep-ph astro-ph.HE
keywords radiationangleelectronelectronsfieldmagnetospheretrajectoriesaccelerating
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Trajectories and radiation of the accelerating electrons are studied in the pulsar magnetosphere approximated as the electromagnetic field of the Deutsch's solutions. Because the electrons are accelerated rapidly to ultra-relativistic velocity near the neutron star surface, the electron velocity vector (and then its trajectory) is derived from the balance between Lorentz force and radiation reaction force, which makes the pitch angle between electron trajectories and magnetic field lines nonzero in most part of the magnetosphere. In such a case, the spectral energy distributions (SEDs) of synchro-curvature radiation for the accelerating electrons with a mono-energetic form are calculated. Our results indicate that: (i) the pitch angle is the function of electron position ($r, \theta, \phi$) in the open field line regions, and increases with increasing $r$ and $\theta$ as well as increasing the inclination angle; (ii) the radius of curvature becomes large along the particle trajectory, and (iii) the SED appears a double peak structure depending on the emission position, where the synchrotron radiation plays an important role in X-ray band and curvature radiation mainly works in GeV band, which is only determined by parameters $\alpha$ and $\zeta$

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