Sonic-Point and Spin-Resonance Model of the Kilohertz QPO Pairs
Abstract
KHz QPOs have now been detected in more than twenty accreting neutron stars in low-mass binary systems. Two kHz QPOs are usually detected in each star. Burst oscillations and two kHz QPOs have recently been detected in the 401 Hz accretion-powered X-ray pulsar SAX J1808.4-3658. In this star the frequency of the burst oscillation is approximately equal to the star's spin frequency nuspin whereas the frequency separation of the two kHz QPOs is approximately nuspin/2. If as expected the frequency of the burst oscillations in other stars is also approximately nuspin, the frequency separation is approximately nuspin in some stars but approximately nuspin/2 in others. A frequency separation approximately equal to nuspin/2 is unexplained in all existing models of the kHz QPOs. Here we propose a modified version of the sonic-point beat-frequency model that can explain within a single framework why the frequency separation is close to nuspin in some stars but close to nuspin/2 in others. As in the original sonic-point model, the frequency nuQPO2 of the upper kHz QPO is close to the orbital frequency nuorb at the radius rsp of the sonic point in the disk flow. We show that magnetic and radiation fields rotating with the star will preferentially excite vertical motions in the disk at the "spin-resonance'' radius rsr where nuorb - nuspin is equal to the vertical epicyclic frequency, producing vertical motions in the disk that modulate the X-ray flux at approximately nuQPO2 - nuspin or approximately nuQPO2 - nuspin/2, depending on whether the disk flow at rsr is smooth or clumped. This sonic-point and spin-resonance model can also explain quantitatively the decrease of the kHz QPO frequency separation with increasing accretion rate that is observed in many sources.
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