Scintillation timescale measurement of the highly active FRB20201124A

Scintillation of compact radio sources results from the interference between images caused by multipath propagation, and can be used to probe the intervening scattering plasma and the velocities of the emitting source and scattering screen. In FRB20201124A, a repeating FRB which recently entered a period of extreme activity, we obtained many burst detections in observations at the Giant Metrewave Radio Telescope (GMRT) and the Effelsberg 100m Radio Telescope. Bursts nearby in time show similar scintillation patterns, and we were able to measure a scintillation timescale by correlating spectra burst pairs, the first such measurement for an FRB. In addition, we form the 2D autocorrelation function (ACF) and secondary spectrum of scintillation, the results of which hint towards anisotropic scattering. The inferred scintillation velocity is $V_{\mathrm{ISS}}\approx (64\pm7) \sqrt{d_{l}/2\,\rm{kpc}}~{\rm km~s}^{-1}$, higher than Earth's velocity for any screen beyond $d_{l} \gtrsim 400\,$pc. From the measured scintillation bandwidth, FRB20201124A is underscattered by a factor of $\sim 20$ compared to the NE2001 model predictions, and has comparatively lower scattering than nearby pulsars. This underscattering, together with the measured scintillation velocity are consistent with a scattering screen more nearby the Earth at $d_{l} \sim 400\,$pc, rather than at $2\,$kpc spiral arm which NE2001 predicts to be the dominant source of scattering. With future measurements, the distance, geometry, and velocity of the scattering screen could be obtained through modelling of the annual variation in $V_{\rm ISS}$, or through inter-station time delays or VLBI. Scintillation/scattering measurements of FRBs could help improve Galactic electron density models, particularly in the Galactic halo or at high Galactic latitudes.