Periodic orbits and their gravitational wave radiations in $γ$-metric

Abstract: The gamma-metric, also known as Zipoy-Voorhees spacetime, is a static, axially symmetric vacuum solution to Einstein's field equations characterized by two parameters: mass and the deformation parameter gamma. It reduces to the Schwarzschild metric when gamma = 1. In this paper we explore potential signatures of the gamma-metric on periodic orbits and their gravitational-wave radiation. Periodic orbits are classified by a rotational number specified by three topological numbers (z, w, v), each triple corresponding to characteristic zoom-whirl behavior. We show that deviations from gamma=1 alter the radii and angular momentum of bound orbits and thereby shift the (z, w, v) taxonomy. We also compute representative gravitational waveforms for certain periodic orbits and demonstrate that gamma != 1 can induce phase shifts and amplitude modulations correlated with changes in the zoom-whirl structure. In particular, larger zoom numbers lead to increasingly complex substructures in the waveforms, and finite deviations from gamma=1 can significantly modify these features. Our results indicate that precise measurements of waveform morphology from extreme-mass-ratio inspirals may constrain deviations from spherical symmetry encoded in gamma.