Overview

I measure the properties of the gas surrounding clusters of recently formed stars in many galaxies. These hot stars produce copious numbers of ultraviolet (UV) photons, where the photons with wavelengths < 912 Å ionize the (predominantly H) gas around them. Within these ionized regions, called HII Regions, H atoms are continuously cycling between being ionized by the young stars and recombining with the free electrons - a process that subsequently produces strong H emission lines. There is also lots of He in HII regions and small amounts of other elements heavier than H and He that we call metals. While small in number, the metals in the gas play important roles in several galaxy evolution processes. One of the most powerful diagnostic tools I use is recording the abundance of these metals, or the metallicity, in a galaxy because the most common metals (such as O, N, and C) are produced by nucleosynthetic processes in stars and the total amount of metals in the gas progressively increases with successive generations of stars. Therefore, the chemical composition of a galaxy serves as a fossil record, encoding the cumulative star formation (SF), accretion, and outflow processes that shaped the present-day gas in galaxies, or interstellar medium (ISM). 

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By observing the the emission features in spectra of HII regions, we can measure features that are sensitive to different gas-phase (nebular) properties such as nebular density, temperature, ionization, metallicity, and stellar population age. Below, you can interact with some theoretical optical spectra of HII regions to see for yourself home different features are affected by these properties.