Prompt Periodicity in the GRB 211211A Precursor: Black-hole or magnetar engine?
Abstract
The merger origin long GRB 211211A was a class (re-)defining event. A precursor was identified with a 1 s separation from the main burst, as well as a claimed candidate quasi-periodic oscillation (QPO) with a frequency 20 Hz. Here, we explore the implications of the precursor, assuming the quasi-periodicity is real. The precursor variability timescale requires relativistic motion with a Lorentz factor 80, and implies an engine driven jetted outflow. The declining amplitude of the consecutive pulses requires an episodic engine with an `on/off' cycle consistent with the QPO. For a black-hole central engine, the QPO can have its origin in Lense-Thirring precession of the inner disk at 6-9 rg (gravitational radii) for a mass M≤4.5 M, and 7 rg for M>4.5 M and dimensionless spin 0.3 - 0.9. Alternatively, at a disk density of 108 - 12 g cm-3, the required magnetic field strength for a QPO via magnetohydrodynamic effects will be on the order B1012 - 14 G. If the central engine is a short lived magnetar or hypermassive neutron star, then a low-frequency QPO can be produced via instabilities within the disk at a radius of 20 - 70 km, for a disk density 109 - 12 g cm-3 and magnetic field 1013 - 14 G. The QPO cannot be coupled to the neutron star spin, as the co-rotation radius is beyond the scale of the disk. Neither engine can be ruled out -- however, we favour an origin for the precursor candidate QPO as early jet-disk coupling for a neutron star -- black hole merger remnant with mass M>4.5 M.
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