CSENG Physics & Astronomy
College of Science & Engineering
Twin Cities
College of Science & Engineering
Twin Cities
Project Title:
Radiative Transport of Resonant Lines
This group is working on the following projects that require MSI's computational and memory capabilities:
- Photons in Astrophysical Environments: This project uses a numerical radiation transfer code called RASCAS that simulates the propagation of photons in astrophysical environments. The goal of this project is to perform the radiation transfer of Lyman alpha photons in idealized galactic environments designed to match model constraints of real galaxies in effort to reproduce the observed Lyman alpha signal in these galaxies. This tests our current understanding of galaxies and make progress towards using the Lyman alpha signal to constrain galaxy properties.
- Constraining the Reionization History via Symbolic Regression: The goal of this project is to find an analytical formula that describes reionization history. The project uses MSI to generate the 21cm signal images using the code SimFast and calculated the reionization history from these images. The equation best that best described the results was searched for via symbolic regression, a genetic programming package method.
- The Blue Compact Dwarf Galaxies in the Dark Energy Survey: This new project will reconstruct the stellar population of galaxies with the spectral energy distribution fitting method using the code "BEAGLE."
- Simulating Galaxies Post-Big Bang: This project uses MSI to simulate galaxies about a billion years after the Big Bang. These galaxies’ space densities and positions on the sky contain information about reionization, the phase change when the universe transitioned from neutral to ionized, which is the phase of universe we live in today. However, key details of reionization are not yet well understood. By creating many realizations of these simulated galaxies with different input parameters, each simulation’s output observables can be compared to those of real data to learn which input parameters reflect reality.
- Euclid Space Telescope Uncertainties: This new project will quantify and minimize the systematic uncertainties facing the Euclid space telescope. It requires MSI resources to work with the extremely large simulations which are necessary in this project.
Project Investigators
Charles Acomb
Sean Bruton
Cody Carr
Annalisa Citro
Wanjia Hu
Mason Huberty
Frank Ning
Professor Claudia Scarlata
Bonnabelle Zabelle
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