Chronicling the Histories of Galaxies at Distances of 1 to 20 Mpc: Simulated Performance of 20-m, 30-m, 50-m, and 100-m TelescopesKnut Olsen, Brent Ellerbroek, and Steve Strom
Presentation to GSMT SWG, October 20, 2005
Context
Hierarchical structure formation:
Primordial fluctuations + CDM + collapse of DM halos, starting with the smallest
Explains:
•Large-scale structure (e.g. White & Rees 1978)
•The morphologies of galaxies (e.g. Kauffmann et al. 1993; Steinmetz & Navarro 2002)
•The globular cluster systems of elliptical galaxies and of the Milky Way halo (Beasley et al. 2002; Searle & Zinn 1978)
Mathis et al. (2002)
Dark matter Gas Stars
Galaxy formation physics
•Gas cooling
•Star formation
•Feedback
•Merging
Abadi et al. (2003)
320 kpc
40 kpc
The angular momentum problem of disk galaxy formation
•Early gas cooling in simulations leads to compact gas disks inside dark matter halos
•Every merger has the opportunity to transfer L outwards, so that baryons lose L to dark matter
Abadi et al. (2003)
The importance of star formation and feedback
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•Feedback inhibits rapid collapse of gas
•Feedback regulates star formation
Robertson et al. (2004)
ELT Stellar Populations Science
•Near IR photometry of resolved stars in nearby galaxies provides a way to extract their entire star formation histories
Crowding, and hence aperture size, is the limiting factor
• Spectroscopy of individual stars supplements the photometric data with more accurate chemical abundance measurements
Sensitivity and crowding can both be limiting factors
M31 observed with Gemini N+NIRI/Altair (Olsen et al., in prep.)
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Stellar Evolution in a Composite Population: M31
Model with constant star formation rate and stepwise increasing metallicity
Girardi et al. (2000) tracks
AO-corrected 8-m performance
Modeling crowding effects
V I
Crowding introduces photometric error through luminosity fluctuations within a single resolution element of the telescope due to the unresolved stellar sources in that element.
To calculate the effects of crowding on magnitudes and colors, we need only consider the Poisson statistics of the luminosity functions (e.g. Tonry & Schneider 1988)
For magnitudes:
For colors:
hi
8 8
30-m vs. 100-m: Analytical results
Magnitudes at which 10% photometry is possible in regions of surface brightness V=22, K=19 for galaxies at the indicated distances.
Issues
Photometric Issues:
Spatial variability of PSF
Time variability of PSF
Absolute calibration
Scientific Issues:
Sample size needed
Field size needed
Filters needed
PSF Simulation
• AO Error sources included
1. Finite number of guide stars and DMs
2. Finite spatial resolution of wavefront sensors and DMs
• Sampled on 49x49 20” wide grid in IJHK for 20-m, 30-m, 50-m, and 100-m telescopes
• Sampled over 12-minute average intervals from hour-long “typical” observation with TMT MASS/DIMM
• 5 atmospheric profiles 4 filters 49 (10) positions 4 telescopes = 3920 (800) PSFs
30-m J PSF grid, profile 1
PSF Simulation
Courtesy of Richard Clare
20-m to 100-m: Simulated scenes (in progress)
•M31 Bulge
•M31 Disk
•NGC 3379 effective radius
•NGC 3379 3x effective radius
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Simulation procedure
•Select appropriate population mix
•Pick stars from stellar isochrones and place in image, making sure to simulate stars well below crowding limit
•Convolve image with PSFs (495 convolutions, combine through weighted average)
•Add sky background and noise
•Perform PSF-fitting photometry
•Correct photometry for Strehl ratio using profile 1 or average of profiles 1 and 5
•Derive best-fit population mix
Coming results
•Demonstrate ability of suite of ELTs to measure the formation epoch of disks vs. bulges vs. ellipticals
•Show effect of likely calibration errors on end results
•Quantify observing strategies
•Recommend instrument FOV, filters, and necessary sample sizes
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