Constraints on Torque-Reversing Accretion-Powered X-ray Pulsars
Abstract
The observed abrupt torque reversals in X-ray pulsars, 4U 1626-67, GX 1+4, and OAO 1657-415, can be explained by transition in accretion flow rotation from Keplerian to sub-Keplerian, which takes place at a critical accretion rate, 1016-1017g/s. When a pulsar system spins up near equilibrium spin before the transition, the system goes into spin-down after transition to sub-Keplerian. If a system is well into the spin-up regime, the transition can cause a sharp decrease in spin-up rate but not a sudden spin-down. These observable types of abrupt torque change are distinguished from the smooth torque variation caused by change of M in the Keplerian flow. The observed abrupt torque reversal is expected when the pulsar magnetic field B* 5× 1011bp-1/2Lx,361/2P*,101/2G where the magnetic pitch parameter bp a few, Lx,36 is the X-ray luminosity in 1036 erg/s, and P*,10 is the pulsar spin period in 10s. Observed quasi-periodic oscillation (QPO) periods tightly constrain the model. For 4U 1626-67, M≈ 2.7× 1016g/s with bp1/2 B*≈ 2× 1012G. We estimate M 6× 1016 g/s and bp1/2B* 5× 1013G for GX 1+4, and M 1× 1017 g/s and bp1/2B* 2× 1013G for OAO 1657-415. Reliable detection of QPOs before and after torque reversal could directly test the model.
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