Looking for Light Pseudoscalar Bosons in the Binary Pulsar System J0737-3039

TL;DR

Numerical calculations of the photon-light-pseudoscalar-boson (LPB) production in the recently discovered binary pulsar system J0737-3039 show a very sharp and significant transition probability in the gamma-ray domain.

Abstract

We present numerical calculations of the photon-light-pseudoscalar-boson conversion in the recently discovered binary pulsar system J0737-3039. Light pseudoscalar bosons (LPBs) oscillate into photons in the presence of strong magnetic fields. In the context of this binary pulsar system, this phenomenon attenuates the light beam emitted by one of the pulsars, when the light ray goes through the magnetosphere of the companion pulsar. We show that such an effect is observable in the gamma-ray band since the binary pulsar is seen almost edge-on, depending on the value of the LPB mass and on the strenght of its two-photon coupling. Our results are surprising in that they show a very sharp and significant (up to 50%) transition probability in the gamma-ray ($>$ tens of MeV) domain. The observations can be performed by the upcoming NASA GLAST mission.

Figures (4)

• Figure 1: Geometry of the model binary pulsar system
• Figure 2: Transition probability versus photon energy for a trajectory of the light beam with an impact parameter $\rho=4 \cdot 10^3$ km.
• Figure 3: Total transmisson of the gamma photon beam emitted by pulsar $A$ versus time. Inset shows the modulation mainly due to the rotation of the magnetic dipole moment of pulsar $B$.
• Figure 4: Exclusion region in the case that the existence of the attenuation is excluded at $10\,\%$ level.