Rapid Rotation of Polarization Orientations in PSR B1919+21's Single Pulses: Implications On Pulsar's Magnetospheric Dynamics

We analyse and model rapid rotations of polarization orientations in PSR B1919+21's single pulses, based on FAST observation data. In more than one third of B1919+21's single pulses, polarization angle (PA) is found to rotate quasi-monotonically with pulse longitude, by over 180 or even 360 degrees. Most of these quasi-monotonic PA curves have negative slopes with respect to pulse longitude. Oscillations of circular polarization fraction accompany these PA rotations. This rapid rotation could be induced by quick change of phase lag between normal wave modes within an individual pulse. We propose a phenomenological model to successfully reproduce the observed polarization rotations in single pulses, and calculate phase lags in a dipolar magnetic field of an aligned rotating pulsar, with a dispersion relation of orthogonal wave modes in strongly magnetized plasma. The weak frequency dependence of observed polarization rotation requires the radio emission height to be low, approximately 10 times the neutron star radius.
Comment: 14 pages, 7 figures. Submitted to ApJL