📝 SummarXiv

Abstract

Disentangling the (co-)evolution of individual galaxy structural components remains a difficult task owing to the inability to cleanly isolate light from spatially overlapping components. In this pilot study of PGC 044931, observed as part of the GECKOS survey, we utilise VIRCAM $H$-band imaging to decompose the galaxy into five photometric components, three of which contribute $>50\%$ of light in given regions: a main disc, a boxy/peanut bulge, and a nuclear disc. When the photometric decompositions are mapped onto MUSE observations, we find remarkably good separation in stellar kinematic space. All three structures occupy unique locations in the parameter space of the ratio of stellar line-of-sight velocity ($\rm{V}_{\star}$) and dispersion, ($\sigma_{\star}$), and high order stellar skew, ($h_{3}$). These clear and distinct kinematic signatures give us confidence to make inferences about the formation history of the individual components from observations of the mean light-weighted stellar age and metallicity of the three components. A clear story emerges: one in which an extended galactic disc hosted continued star formation, possibly with the addition of accreted pristine gas. Within the disc, a bar formed and buckled early, building a nuclear disc that continued to enrich via multiple generations of star formation. These results exemplify how careful photometric decompositions, combined with well-resolved stellar kinematic information, can help separate out age-metallicity relations of different components and therefore disentangle the formation history of the galaxy. The results of this pilot survey are applicable to modern, well-resolved spectroscopic galaxy surveys.