Connecting the Baryons: Multiwavelength Data for SKA HI Surveys

TL;DR

This paper discusses how combining SKA HI survey data with multiwavelength observations enhances understanding of galaxy evolution by analyzing baryonic processes and environmental effects.

Contribution

It reviews the scientific motivations and current plans for integrating multiwavelength data with SKA HI surveys to study galaxy evolution comprehensively.

Findings

Multiwavelength data enables detailed analysis of baryonic processes.

Combining datasets improves understanding of galaxy evolution.

Current plans include LSST, Euclid, ALMA, and others.

Abstract

The science achievable with SKA HI surveys will be greatly increased through the combination of HI data with that at other wavelengths. These multiwavelength datasets will enable studies to move beyond an understanding of HI gas in isolation to instead understand HI as an integral part of the highly complex baryonic processes that drive galaxy evolution. As they evolve, galaxies experience a host of environmental and feedback influences, many of which can radically impact their gas content. Important processes include: accretion (hot and cold mode, mergers), depletion (star formation, galactic winds, AGN), phase changes (ionised/atomic/molecular), and environmental effects (ram pressure stripping, tidal effects, strangulation). Governing all of these to various extents is the underlying dark matter distribution. In turn, the result of these processes can significantly alter the baryonic states in which material is finally observed (stellar populations, dust, chemistry) and its morphology (galaxy type, bulge/disk ratio, bars, warps, radial profile). To fully understand the evolution of HI and the role it plays in galactic evolution requires the ability to quantify each of these separate processes, and hence to coordinate SKA HI surveys with extensive multi-band photometric and spectroscopic campaigns. In addition, multiwavelength data is essential for statistical methods of HI analysis such as HI stacking and intensity mapping cross-correlations. In this chapter, we examine some of the principal science motivations for acquiring multiwavelength data to match that from the extragalactic SKA HI surveys, and review the currently planned capacity to achieve this (eg. LSST, Euclid, W-FIRST, SPICA, ALMA, and 4MOST).