GRACE: The Grism Reionization And Cosmic Evolution Survey
Program ID 2003
Science Category Intergalactic Medium
Program Type GAS
Hours 420.9
Category Large
Principal Investigator Sangeeta Malhotra
PI Institution NASA Goddard Space Flight Center
Co-Investigators
  • James Rhoads (NASA Goddard Space Flight Center)
  • Gregory Rudnick (University of Kansas)
  • Isak Wold (NASA Goddard Space Flight Center)
  • Mainak Singha (NASA Goddard Space Flight Center)
  • Ayan Acaryya (Istituto di Astrofisica INAF Padova)
  • Tri Astraatmadja (Space Telescope Science Institute)
  • Devontae Baxter (UC San Diego)
  • Tamas Budavari (Johns Hopkins University)
  • Adam Burgasser (Dept. Astronomy & Astrophysics, UC San Diego)
  • Nima Chartab (Caltech/IPAC)
  • Kai-Feng Chen (Massachusetts Institute of Technology)
  • Vicente Estrada-Carpenter (Arizona State University)
  • Xiaohui Fan (University of Arizona)
  • Rose Finn (Siena University)
  • Ben Forrest (University of California, Davis)
  • Yuichi Harikane (The University of Tokyo)
  • Jacqueline Hewitt (Massachusetts Institute of Technology)
  • Anne Hutter (University of Vienna)
  • Akio Inoue (Waseda University)
  • Pascale Jablonka (Ecole Polytechnique Federale de Lausanne)
  • Rolf Jansen (Arizona State University, School of Earth & Space Exploration, Tempe AZ 85287-1404, U.S.A.)
  • Anton Koekemoer (Space Telescope Science Institute)
  • Crystal Martin (UCSB)
  • Jasleen Matharu (Max Planck Institute for Astronomy (MPIA))
  • Ivelina Momcheva (Max Planck Institute for Astronomy)
  • Andrew Newman (Carnegie Institution for Science)
  • Allison Noble (Arizona State University)
  • Masafusa Onoue (Waseda University)
  • Masami Ouchi (NAOJ / The University of Tokyo)
  • Gwen Rudie (Carengie Science)
  • Benedetta Vulcani (INAF - OaPD)
  • Feige Wang (University of Michigan)
  • Peter Watson (INAF-OAPd, Padova, Italy)
  • Jinyi Yang (University of Michigan)
  • Aaron Yung (Space Telescope Science Institute)
  • Erik Zackrisson (Uppsala University)
  • Sangeeta Kumar (NASA Goddard Space Flight Center)
  • Yichen Liu (University of Arizona)
  • Sambit Giri (University of Stockholm)
  • Gillian Wilson (University of California, Merced)
  • Yannick Bahe (University of Nottingham)
  • Ruari Mackenzie (Ecole Polytechnique Federale de Lausanne)
  • Michael Cooper (University of California, Irvine)
  • Jeffrey Newman (University of Pittsburgh)
  • Ali Ahmad Khostovan (University of Kentucky)
  • Elisabeth Krause (University of Arizona)
  • Wei Leong Tee (Pennsylvania State University)
  • Syeda Lammim Ahad (University of Waterloo)
  • Nina Hatch (University of Nottingham)
  • Adam Muzzin (York University, Toronto)
  • Rhea-sylvia Remus (Ludwig-Maximilians University Munich)
  • Lukas Kimmig (Ludwig-Maximilians University Munich)
  • Jean-Gabriel Cuby (Canada France Hawaii Telescope)
Abstract GRACE is an ultradeep grism survey of 1.5 deg^2 at 40 hours depth and 2.4 deg^2 at >10 hours depth, designed as a maximally efficient survey of LyA emitters(LAE) at z=7-10 to obtain definitive measurements of the epoch and pace of reionization. End-to-end simulations of the Roman grism show that 40 hour depth detects a line flux of 1e-17 ergs/cm^2/s at 5-sigma, reaching the characteristic luminosity L* of LAEs at z=7-9. The area yields excellent statistics for testing a range of models allowed by JWST constraints, and will increase the known sample of z > 7 LAEs by at least 10x. The same data set will yield a large, densely sampled volume at cosmic noon that contains many robust protoclusters placed in the cosmic web. The high resolution of Roman’s grism and proposed sensitivity optimizes detection and characterization of emission and absorption features to determine the star formation history (SFH), star formation rate (SFR), metallicity, and precise cartography in the cosmic web at z=1.5-3 - connecting >10 Mpc scales to 1 Kpc scales. GRACE answers questions like “how did galaxies influence their environment?” and “how did the environment shape galaxies?” in the first 3/4 of the universe’s history. We will deliver 290,000 emission-line redshifts to train photo-z’s for faint galaxies in the redshift desert. GRACE will also determine the faint end of the AGN luminosity function independent of color selection, fill gaps in the redshift evolution of little red dots, find and characterize Galactic M/L/T/Y dwarfs, and enable a kinematic lensing pilot. These transformative goals all REQUIRE a survey that is at least 6 times deeper than HLWAS-deep with higher spectral resolution than HLTDS-deep. GRACE bridges a large gap in depth and area between JWST and Roman/Euclid surveys, and therefore leaves a legacy above and beyond the proposed science. A deep, early survey with repeated observations of a single field will characterize systematics undetectable in shallower data.
Summary of Observations GRACE is an ultradeep WFI grism spectroscopic survey to construct a sensitive 3D map of galaxies covering 1.5 deg^2. Located in the CDFS, the survey utilizes a circular six-pointing tiling pattern to ensure uniform field coverage regardless of the position angle (PA). The strategy employs 48 PAs (SP_500_16, BOXGAP9_1). Fully accounting for dithering and roll angle variation, GRACE will achieve an on-source integration time of t_exp > 40 hours over 1.5 deg^2 (and t_exp > 10 hours over a total area of 2.4 deg^2). This depth reaches a 5sigma emission-line sensitivity of 10^-17 erg/cm^2/s over the 1.5 deg^2 full-depth survey area. The grism observations are paired with imaging in the Y106, J129, H158, and F184 filters. Using 3 ks exposures per filter, we achieve 5sigma depths ranging from 27.9 to 27.1 mag. We have designed the 6-pointing grism observations to always be accompanied by the same 6-pointing imaging configuration, assuring matching PA distributions. Overall, we request 360 hrs for GRISM observations and 20 hrs for YJHF imaging, with APT overheads this totals to a 421 hr survey. We have specified a wide range of V3 position angles in our experimental design, to yield high quality grism spectra for all objects in the field while retaining considerable scheduling flexibility, and also to ensure a range of scheduling epochs that will support spectroscopic time-domain investigations. Additionally, our field (CDFS) does not conflict with Galactic bulge scheduling seasons. We can work with the science operations center to make further adjustments to our roll angle constraints if needed for increased scheduling flexibility.