We observed $\gamma$-ray burst (GRB) 221009A using Very Long Baseline Interferomety (VLBI) with the European VLBI Network (EVN) and the Very Long Baseline Array (VLBA), over a period spanning from 40 to 262 days after the initial GRB. The high angular resolution ($\sim$mas) of our observations allowed us, for the second time ever, after GRB 030329, to measure the projected size, $s$, of the relativistic shock caused by the expansion of the GRB ejecta into the surrounding medium. Our observations support the expansion of the shock with a $>4\sigma$-equivalent significance, and confirm its relativistic nature by revealing an apparently superluminal expansion rate. Fitting a power law expansion model, $s\propto t^a$, to the observed size evolution, we find a slope $a=1.3_{-0.4}^{+0.2}$, which is steeper than expected from either a forward shock (FS) or reverse shock (RS) model, implying an apparent acceleration of the expansion. Fitting the data at each frequency separately, we find different expansion rates, pointing to a frequency-dependent behaviour. We show that the observed size evolution can be reconciled with a RS plus FS in the case of a wind-like circum-burst medium, provided that the two shocks dominate the emission at different frequencies and, possibly, at different times.
Comment: Revised version after first round of peer review