Abstract
Extreme-mass-ratio and intermediate-mass-ratio binaries with a millisecond pulsar are gravitational-wave sources that emit also electromagnetic radiation. The millisecond pulsars in these binaries have complex orbital and spin dynamics, which are observable because of spin–orbit and spin–spin coupling (through spin–curvature interaction). The strengths of the couplings generally depends on the mass ratio between the pulsar and the black hole. The narrow mass range of neutron stars gives an advantage in parameter extraction as it greatly reduces the search space, in particular, in the determination of the black-hole mass, in gravitational wave experiments and radio pulsar timing observations. Extreme-mass-ratio and intermediate-mass-ratio binaries with a millisecond pulsar will help to resolve the astrophysical problems, concerning the applicability of the M-σ relation for galactic spheroids extending to the very low-mass galaxies and whether or not low-mass dwarf galaxies and globular clusters would harbour a nuclear intermediate-mass black hole. The high-precision that can be achieved in gravitational wave experiments and radio pulsar timing observations will provide an opportunity to directly detect gravitational clock effects that are arisen from spin couplings. Radio monitoring of the orbital and spin evolution of the millisecond pulsar in an extreme-mass-ratio binary can be used as a bootstrap method for correcting the drifts in the phases in the gravitational waves from the extreme-mass-ratio and intermediate-mass-ratio binaries caused by self-force.
Highlights
Extreme-mass-ratio binarys (EMRBs) and intermediate-mass-ratio binarys (IMRBs) are gravitational wave (GW) sources that are expected to be detected by the future space GW observatory Laser Interferometric Space Antenna (LISA)
The spin–spin and spin–orbit coupling between the millisecond pulsar (MSP) and the black hole (BH) lead to non-planar orbital motion and precessions in the spin and the orbit of the pulsar
The couplings have observational signatures that can be identified in the GWs from the binary and pulsed radio radiation from the MSP
Summary
Extreme-mass-ratio binarys (EMRBs) and intermediate-mass-ratio binarys (IMRBs) are gravitational wave (GW) sources that are expected to be detected by the future space GW observatory Laser Interferometric Space Antenna (LISA) (see [1,2]). EMRBs and IMRBs containing a millisecond pulsar (MSP) are particular important, as the presence of the pulsar (a neutron star) guarantees an electromagnetic counterpart of these GW sources These binaries are a useful apparatus for the studies of various astrophysics and fundamental physics due to the stability of the MSPs’s rotation (see, e.g., [3]), which provides a reliable local timing reference. This work examines how the multi-messenger studies of EMRBs with a MSP would help to verify the extension of the M-σ relation for galactic spheroids to the very low-mass dwarf galaxies and whether or not intermediate-mass nuclear BHs reside in low-mass galaxies and globular clusters It accesses the observability of gravitational clock effects arisen from spin couplings in EMRBs and IMRBs and the possibility of obtaining a bootstrap scheme to correct self-force effects in the GWs from EMRBs that contain a MSP using radio pulsar monitoring observations
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