Persistent radio sources associated with fast radio bursts: Implications from magnetar progenitors
Abstract
The rare association of three persistent radio sources (confirmed PRS1 and PRS2, candidate PRS3) with repeating fast radio bursts (FRB 20121102A, 20190520B, 20201124A) offers a unique probe into their magneto-ionic environments. PRSs are attributed to synchrotron emission from relativistic charged particles of magnetar wind nebula (MWN) powered by spin-down magnetohydrodynamic wind or internal magnetic field decay. Using a multizone hydrodynamic model, we track MWN evolution to constrain magnetar progenitor properties. For PRS1 and PRS2, we find an equipartition radius Req 0.1 pc that is consistent with the radio scintillation estimates (> 0.03 pc) and radio imaging limits (<0.7 pc). This compact size favors low expansion speeds and large initial spin periods, Pi 10 ms, ruling out millisecond magnetar progenitors. Given Pi 10 ms, a current size of 0.1 pc, a supernova kinetic energy E SN 1050-1051 erg and an ejecta mass M 3-10 \; M, the PRS age is t 10-102 yr. PRSs with t>20 years require an internal field (Bint 1016-1016.5\;G) with a decay timescale td 10-102.5 yr. The slowest field decay (td,max 500 yr) favors sub-energetic supernovae (ESN 1050 erg) with massive ejecta (M 10\; M) and low ionization fraction ( 3\% ). For the sub-energetic scenario for the confirmed PRSs, we predict a cooling break at 100-150 gigahertz at 20-40 \; μ Jy and self-absorption near 200 megahertz at 180\; μ Jy. For PRS3, a rotation-powered MWN is viable only if t 10 yr; an inverted spectrum beyond 150 gigahertz would rule out this scenario.
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