Can gas prevent the destruction of thin stellar discs by minor mergers?

We study the effect of dissipational gas physics on the vertical heating and thickening of disc galaxies during minor mergers. We produce a suite of minor merger simulations for Milky-Way-like galaxies. This suite consists of collisionless simulations as well as hydrodynamical runs including a gaseous component in the galactic disc. We find that in dissipationless simulations minor mergers cause the scaleheight of the disc to increase by up to a factor of similar to 2. When the presence of gas in the disc is taken into account, this thickening is reduced by 25 per cent (50 per cent) for an initial disc gas fraction of 20 per cent (40 per cent), leading to a final scaleheight z(0) between 0.6 and 0.7 kpc (for a sech2 profile), regardless of the initial scaleheight. We argue that the presence of gas reduces disc heating via two mechanisms: absorption of kinetic impact energy by the gas and/or formation of a new thin stellar disc that can cause heated stars to recontract towards the disc plane. We show that in our simulations most of the gas is consumed during the merger and thus the regrowth of a new thin disc has a negligible impact on the z(0) of the post-merger galaxy. Final disc scaleheights found in our simulations are in good agreement with studies of the vertical structure of spiral galaxies where the majority of the systems are found to have scaleheights of 0.4 less than or similar to z(0) less than or similar to 0.8 kpc. We also found no tension between recent measurements of the scaleheight of the Milky Way thin disc and results coming from our hydrodynamical simulations. Even if the Milky Way did experience a recent 1:10 merger it is possible to reproduce the observed thin disc scaleheight, assuming that the disc contained at least 20 per cent gas (similar to the gas fraction today) at the time of the merger. We conclude that the existence of a thin disc in the Milky Way and in external galaxies is not in obvious conflict with the predictions of the cold dark matter model.