A general framework describing how stars form has existed for decades. However, the details of how mass flows from larger-scale structures onto stars remains unclear. There is some evidence that the growth of stars is episodic in nature. Despite there being some evidence to support this picture, the true growth history of stars remains unknown. The investigator will perform theoretical work to reveal how stars gain their mass. This research will also provide training and professional development opportunities to undergraduate students and support the expansion of public astronomy outreach offerings in rural Vermont. Mass accretion onto at least some stars exhibits strong temporal variability, with direct detection of occasional large-amplitude bursts. In the episodic accretion scenario, large accretion luminosity changes will modify the temperature of the surrounding material, moving the boundaries between gas and solid phases for various species and driving irreversible chemical changes that will persist into the planet formation epoch. The investigator will assess the viability of stochastic and secular accretion scenarios by coupling existing (magneto)hydrodynamical simulations with evolutionary radiative transfer models, generating synthetic observations of protostars, and performing an apples-to-apples comparison with published observations. This work will ultimately investigate the physics governing accretion onto young stars and the role played by accretion v