H. A. Adarsha MCNS, India, Chandrachur Chakraborty MCNS, India, Sudip Bhattacharyya TIFR, India

We introduce a novel mechanism -- Magnetically Arrested Transmutation (MAT) -- to account for the observed absence of ordinary pulsars near the Galactic centre, a longstanding puzzle known as the missing pulsar problem and the over-representation of magnetic white dwarfs in the same region. In this scenario, compact stars capture and accumulate dark matter, eventually forming an endoparasitic black hole (EBH) of initial mass $M_0$ at their core. Although such EBHs generally grow by accreting host matter, we show that sufficiently strong core magnetic fields can establish pressure equilibrium, thereby stalling further accretion and halting the star's transmutation into a black hole. We derive the conditions for MAT to occur, identifying a critical parameter $\beta$, which encapsulates the interplay between the magnetic field strength, host matter density, and EBH mass. For $0 < \beta \leq 4/27$, the growth of the EBH is arrested, limiting its final mass ($M_{\rm f}$) to $M_0 < M_{\rm f} \leq 3/2 M_0$, whereas for $\beta > 4/27$, full transmutation may ensue. This framework offers a plausible unified explanation for the absence of ordinary pulsars and the survival of the magnetar PSR J1745-2900, and the elevated population of magnetic white dwarfs, in the Galactic centre, and hence could be tested and should have implications for understanding dark matter and compact objects.