http://arxiv.org/abs/1904.10433
PSR J1023+0038 is the first millisecond pulsar discovered to pulsate in the visible band; such a detection took place when the pulsar was surrounded by an accretion disk and also showed X-ray pulsations. We report on the first high time resolution optical/X-ray/IR/UV observational campaign of this transitional pulsar in the disk state. Optical and X-ray pulsations were detected simultaneously in the X-ray high intensity mode in which the source spends $\sim$ 70% of the time, and both disappeared in the low mode, indicating a common underlying physical mechanism. In addition, optical and X-ray pulses were emitted within a few km, had similar pulse shape and distribution of the pulsed flux density compatible with a power-law relation $F_{\nu} \propto \nu^{-0.7}$ connecting the optical and the 0.3-45 keV X-ray band. Optical pulses were detected also during flares with a pulsed flux reduced by one third with respect to the high mode; the lack of a simultaneous detection of X-ray pulses is compatible with the lower photon statistics. We show that channelled accretion cannot account for the optical pulsed luminosity ($\sim 10^{31}$ erg/s), whereas magnetospheric rotation-powered pulsar emission requires extremely efficient conversion of spin-down power into pulsed optical and X-ray emission. We propose that optical and X-ray pulses are produced by synchrotron emission from the intrabinary shock that forms where a striped pulsar wind meets the accretion disk, within a few light cylinder radii away, $\sim$ 100 km, from the pulsar.
A. Papitto, F. Ambrosino, L. Stella, et. al.
Wed, 24 Apr 19
10/51
Comments: 24 pages, 13 figures, submitted to ApJ on 2019, January 18