The Event Horizon Telescope: exploring strong gravity and accretion physics

TL;DR

The paper discusses how the Event Horizon Telescope's advancements enable detailed studies of black hole environments, including the detection of the photon ring and accretion flow structures, through improved imaging and analysis techniques.

Contribution

It demonstrates the potential of the EHT to detect strong gravity signatures and constrain accretion models using enhanced instrumentation and multi-frequency observations.

Findings

Detection prospects for the photon ring with upgraded EHT.

Improved imaging precision with closure phases.

Constraints on accretion models and variability detection.

Abstract

The Event Horizon Telescope (EHT), a global sub-millimeter wavelength very long baseline interferometry array, is now resolving the innermost regions around the supermassive black holes Sgr A* and M87. Using black hole images from both simple geometric models and relativistic magnetohydrodynamical accretion flow simulations, we perform a variety of experiments to assess the promise of the EHT for studying strong gravity and accretion physics during the stages of its development. We find that (1) the addition of the LMT and ALMA along with upgraded instrumentation in the "Complete" stage of the EHT allow detection of the photon ring, a signature of Kerr strong gravity, for predicted values of its total flux; (2) the inclusion of coherently averaged closure phases in our analysis dramatically improves the precision of even the current array, allowing (3) significantly tighter constraints on plausible accretion models and (4) detections of structural variability at the levels predicted by the models. While observations at 345 GHz circumvent problems due to interstellar electron scattering in line-of-sight to the galactic center, short baselines provided by CARMA and/or the LMT could be required in order to constrain the overall shape of the accretion flow. Given the systematic uncertainties in the underlying models, using the full complement of two observing frequencies (230 and 345 GHz) and sources (Sgr A* and M87) may be critical for achieving transformative science with the EHT experiment.