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----- Attempting Submission 1 (Thu Mar 17 18:27:41 GMT 2022) -----
HST Phase I Proposal 2756  successfully submitted.
Receipt: # 2756-1

----- Attempting Submission 2 (Thu Mar 17 22:19:50 GMT 2022) -----
HST Phase I Proposal 2756  successfully submitted.
Receipt: # 2756-2

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HST Phase I Proposal 2756  successfully submitted.
Receipt: # 2756-3

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   <ProposalInformation
      Category="AR"
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      <Title>Quantifying Systematics in the JAGB Method Distance Scale in M31</Title>
      
      <Abstract>JAGB stars, a subset of carbon-rich, thermally-pulsating AGB stars, have well-defined, low-dispersion absolute magnitudes in the near infrared, making them excellent standard candles. The JAGB star extragalactic distance indicator has been shown to be on par with the Cepheid and TRGB methods in both precision and accuracy, and therefore capable of acting as a powerful cross-check on SN Ia host galaxy distances. However, because the JAGB method is still relatively novel, it has not been as well tested as the Cepheid and TRGB distance indicators. We propose to leverage archival data from the Panchromatic Hubble Andromeda Treasury (PHAT) in M31 to quantify how the host galaxy star formation history, internal reddening, and metallicity may affect the JAGB method distance scale. The JAGB method has already been shown to be highly precise; understanding the systematics of even these small effects will further increase its precision. Once the potential systematics of the JAGB method have been thoroughly investigated, the JAGB method can be used to provide an independent local measurement of H0, and cross-check TRGB and Cepheid distances. As a bonus, this proposal will help provide observational constraints on the carbon star luminosity function in different stellar environments, directly guiding theoretical models of carbon star evolution which includes winds, dredge-ups, and hot-bottom burning.</Abstract>
      
      <PrincipalInvestigator
         Honorific="Ms."
         FirstName="Abigail"
         LastName="Lee"
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         UniqueID="28167"
         Institution="University of Chicago"
         Country="USA"
         State="IL"
         Contact="true" />
      
      <CoInvestigator
         Honorific="Prof."
         FirstName="Wendy"
         MiddleInitial="L."
         LastName="Freedman"
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         FirstName="Barry"
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         Institution="Carnegie Institution of Washington"
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         FirstName="In Sung"
         LastName="Jang"
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         Institution="University of Chicago"
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      <CoInvestigator
         Honorific="Ms."
         FirstName="Kayla"
         MiddleInitial="A."
         LastName="Owens"
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         Institution="University of Chicago"
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      <TeamExpertise>Ms. Abigail Lee has years of expertise in HST data analysis for ACS and WFC3. As a graduate student at UChicago, she has published three papers on the JAGB method, the distance indicator discussed in this proposal. 

Professor Wendy L. Freedman and Dr. Barry F. Madore share a long-standing mutual interest and applied expertise in determining the expansion rate of the Universe, having pioneered the use of Cepheid variables and the TRGB Method, in the optical and in the near infrared. Both were founding members of the original HST Key Project on the Hubble constant and they have over 100 refereed papers on this topic.

Dr. Jang is a postdoctoral fellow at the University of Chicago and has upwards of 10 years of experience analyzing HST ACS and WFC3 data.

Ms. Kayla Owens is a graduate student working with Prof. Freedman and Dr. Madore at the University of Chicago. She has considerable experience working with HST imaging data. 

All of the people listed above have been active participants in the Carnegie-Chicago Hubble Constant Program and have years of experience reducing, analyzing and using HST imaging data.
With specific regard to this program, Lee, Freedman, and Madore have pioneered the calibration and application of the JAGB Method to the extragalactic distance scale.</TeamExpertise>
      
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         <ScientificCategory>Stellar Populations and the Interstellar Medium</ScientificCategory>
         
         <SecondaryScientificCategory>Large Scale Structure of the Universe</SecondaryScientificCategory>
         
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            Keyword="Intermediate Type Stars" />
         
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            Keyword="Large-Scale Structure Of The Universe" />
         
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            Keyword="Local Group" />
         
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            Keyword="Stellar Distance" />
         
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