The Milky Way's Fermi Bubbles: Echoes of the Last Quasar Outburst?

TL;DR

This paper proposes that the Fermi Bubbles are remnants of a large-scale outflow from the Milky Way's central black hole, triggered by a past accretion event coinciding with a star formation episode, explaining their symmetry and gamma-ray emission.

Contribution

It introduces a novel outflow model from Sgr A* as the origin of the Fermi Bubbles, linking black hole activity with galactic gamma-ray structures and star formation history.

Findings

Outflow focused into symmetrical lobes by gas pressure

Estimated accreted mass matches star formation mass

Gamma-ray emission powered by cosmic rays from shocks

Abstract

{\it Fermi}-LAT has recently detected two gamma ray bubbles disposed symmetrically with respect to the Galactic plane. The bubbles have been suggested to be in a quasi-steady state, inflated by ongoing star formation over the age of the Galaxy. Here we propose an alternative picture where the bubbles are the remnants of a large-scale wide-angle outflow from \sgra, the SMBH of our Galaxy. Such an outflow would be a natural consequence of a short but bright accretion event on to \sgra\ if it happened concurrently with the well known star formation event in the inner 0.5 pc of the Milky Way $\sim 6$ Myr ago. We find that the hypothesised near-spherical outflow is focussed into a pair of symmetrical lobes by the greater gas pressure along the Galactic plane. The outflow shocks against the interstellar gas in the Galaxy bulge. Gamma--ray emission could be powered by cosmic rays created by either \sgra\ directly or accelerated in the shocks with the external medium. The Galaxy disc remains unaffected, agreeing with recent observational evidence that supermassive black holes do not correlate with galaxy disc properties. We estimate that an accreted mass $\sim 2 \times 10^3\msun$ is needed for the accretion event to power the observed {\it Fermi}--LAT lobes. Within a factor of a few this agrees with the mass of the young stars born during the star formation event. This estimate suggests that roughly 50% of the gas was turned into stars, while the rest accreted onto \sgra. One interpretation of this is a reduced star formation efficiency inside the \sgra\ accretion disc due to stellar feedback, and the other a peculiar mass deposition geometry that resulted in a significant amount of gas falling directly inside the inner $\sim 0.03$ pc of the Galaxy.