Equatorial Circular Motion of Charged Test Particles in a Weakly Magnetized Taub--NUT Background

Abstract

We study circular motion of charged test particles on the equatorial slice of a Taub--NUT black hole with Manko--Ruiz parameter C, immersed in a weak external magnetic field introduced via Wald's prescription. Because the Taub--NUT metric is not reflection-symmetric about the equator once l≠ 0, generic charged orbits lie on cones x=θ≠ 0 rather than on the equatorial plane. We therefore analyse constrained circular orbits obtained by imposing x= x=0, and we exhibit in closed form the residual angular constraint that a fully self-consistent orbit would have to satisfy. Within this scope we derive the circularity and marginal-stability conditions and study how B and C shift the ISCO radius for prograde and retrograde branches. Increasing B monotonically decreases rISCO; the sign of the particle charge splits the two branches, with the ordering reversed between prograde and retrograde motion; and C contributes only subleading corrections. The extension to self-consistent conical orbits is the natural direction for follow-up work.