The impact of diffuse Galactic emission on direction-independent gain calibration in high-redshift 21 cm observations

Abstract: This study examines the impact of diffuse Galactic emission on sky-based direction-independent (DI) gain calibration using realistic forward simulations of Low-Frequency Array (LOFAR) observations of the high-redshift 21 cm signal of neutral hydrogen during the Epoch of Reionization (EoR). We simulated LOFAR observations between 147 - 159 MHz using a sky model that includes a point source catalogue and diffuse Galactic emission. The simulated observations were DI-gain calibrated with the point source catalogue alone, utilising the LOFAR-EoR data analysis pipeline. A full power spectrum analysis was conducted to assess the systematic bias introduced by DI-gain calibration using complete and incomplete sky models, relative to thermal noise. Additionally, the cross-coherence between observation pairs was computed to determine whether DI-gain calibration errors are coherent or incoherent in specific regions of power spectrum space as a function of integration time. We find that DI-gain calibration with an incomplete sky model that omits diffuse Galactic emission introduces a systematic bias in the power spectrum for $k_{\parallel}$ bins < 0.2 $h\,\mathrm{Mpc}^{-1}$. The power spectrum errors in these bins are coherent; therefore, the resulting bias can be mitigated during the foreground removal step. In contrast, errors for $k_{\parallel}$ > 0.2 $h\,\mathrm{Mpc}^{-1}$ are largely incoherent and average down as noise. We conclude that missing diffuse Galactic emission in the sky model is not a significant contributor to the excess noise observed in the current LOFAR-EoR upper limit results on the 21 cm signal power spectrum.