Off-Axis Telescopes for Dark Energy Investigations
SPIE 7731-52, 30 June 2010M.Lampton (UC Berkeley)
M. Sholl (UC Berkeley)M. Levi (LBNL Berkeley)
Dark Energy?
• A name we give to describe the observed acceleration of the expansion of the universe
• Could be the “cosmological constant” in GR– Very hard to explain why that isn’t huge, or zero
• Could be something else!– Varying over time; maybe even over space!
• Different theories predict how DE evolves• Test: BAO – a standard ruler, shows expansion history• Test: SNe – a standard candle, shows expansion history• Test: WL – shows growth of structure over history
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Baryon Acoustic Oscillations: standard rulers http://mwhite.berkeley.edu/BAO/bao_iucca.pdf
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Komatsu et al arXiv 1001.4538
Then: z=1100Ruler = 400kly
Now: z=0Ruler = 400Mly
How to measure redshifts of 30 million galaxies per year, with σz = 0.001/(1+z)?Use slitless spectroscopy!
Tighter PSF => smaller σz => Bigger Survey
Type Ia Supernovae: standard candles
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Kowalski et al., ApJ 686, 749 (2008)
explosion
Peak spectrum
Reference spectrum
Figures courtesy A.G.Kim 2010
Red: SNR at peak. Others: earlier and later times
Tighter PSF => Less Texp > Bigger Survey
Weak Lensing: probe growth of structure
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http://www.cita.utoronto.ca/~hoekstra/lensing.html
Jouvel et al., “Designing Future Dark Energy Missions” A&A 504, 359 (2009)
Rhalf, arcseconds
Strong lensing A2218
Weak lensing statistical concept
Space based WL program seeks 30 galaxies/sqarcmin, 0.2 arcsec, 25th mag galaxies; needs good PSF and stability
Tight PSF and small pixels are mandatory to get these galaxies
JDEMInterim Science Working Group Report http://jdem.lbl.gov (2010)
Science Objective Design A Design B
Supernova Redshift Survey
1500 supernovaeRedshifts 0.2<z<1.5
Tiered survey areas for discoverySame as Design A
BAO Galaxy SurveyHalpha flux 2e-16 erg/cm2sec
Spectroscopic redshifts 1.3<z<2.0RMS z < 0.001·(1+z)
16000 square degrees in 1.5 years
Same as Design A
Weak Lensing Survey none10000 square degrees
30 galaxies per square arcminRedshifts from Photo-Z
1e5 spectro calibration galaxies
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JDEMInterim Science Working Group Report http://jdem.lbl.gov (2010)
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Element Design A Design BTelescope 1.1m unobscured aperture TMA Similar to A
Wide field imager For BAO centroids
For SN discovery searches In Design B, for cosmic shear
0.5 square degree FoVTwo bands: 0.7-1um, 1-1.5um32 Mpixels, each 0.45arcsec
HgCdTe 2Kx2K
Similar to ASimilar to A
More & finer pixelsHgCdTe and/or Si CCD
Slitless prism spectrometer For BAO galaxy redshifts
0.5 square degree FoVOne waveband 1.5 – 2.0 um32 Mpixels, each 0.45arcsec
Similar to ASimilar to ASimilar to A
Supernova Slit or IFU spectrometer Light curves, spectra, host redshifts
Narrow field (a few arcseconds)One waveband 0.4 – 2.0um
Similar to ASimilar to A
Key Mission Requirement: Survey Rate
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2half
2
2min
R πAEFFoV
BSNRΔλN0.25 RateSurvey
This talk
• Simple formulas like…
• JSIM: a public web tool created by M.Levi • http://jdem.lbl.gov/ “Exposure Time Calculator”
• JSIM inputs are high-level mission parameters– Telescope Aperture, central obstruction size, WFE…– Field of view on sky, pixel scale, focal length, number of sensor chips– Detector Technology: pixel size, pixels per chip, waveband, QE curve– Fraction of time allocated to BAO, SNe, WL, calibration, downlink, … – Mission duration
• JSIM outputs are “high level” mission yield & FOMs• JSIM outputs also available at “low level” individual FO’s.• Bottom line: smaller point spread function boosts yields
JSIM Internal Databases & Models http://jdem.lbl.gov/ “Exposure Time Calculator”
• BAO emission line galaxy Hα flux, size, and redshift distribution– Ilbert et al 2005
• WL galaxy magnitude, size, and redshift distribution– Leauthaud et al 2008 zCOSMOS; Jouvel et al 2009
• Supernova occurrence rate vs redshift– Lesser of published curves by Sullivan et al 2006 and Dahlen et al 2008
• Zodiacal light vs wavelength and ecliptic latitude– Leinert et al 1998; Aldering 2001
• Optical point spread function– MTF contributions from pupil diffraction and WFE via Fischer’s Hopkins Ratio– Gaussian two dimensional random attitude control errors– Sensor pixel size; interpixel diffusion
• Sensor contributions (dark current, read noise, QE)• Signal-to-noise ratio estimation
– Optimal extraction, convolving galaxy exponential with system PSF
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Obscured vs Unobscured Focal TMAsThese historical examples are both focal but afocal configurations are equally good
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Obscured, here with 1.2m aperturef/11; 13mEFL 18um = 0.285”FoV = 0.73x1.46deg =166 x 330mmEasy fit to 4x8 sensors.< 3umRMS theoretical PSFReal Cassegrain image: control stray lightReal exit pupil: control of stray heatBest with auxiliary optics behind PM;Easy heat path for one focal plane. Korsch,D., A.O. 16 #8, 2074 (1977)
Cook,L.G., Proc.SPIE v.183 (1979)
Unobscured, also with 1.2m aperturef/11, 13mEFL, 18um=0.285”FOV = 0.73 x1.46deg = 166x330mmEasy fit to 4x8 sensors.< 3umRMS theoretical PSFReal Cassegrain image: control stray lightReal exit pupil: control of stray heatEasy heat path to cold side of payload for entire SM-TM-FP assembly; can accommodate several focal planes.
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PSFs For Unaberrated PupilsScaled for equal incident flux and equal PM diameter Shows both obstructed light loss and diffraction loss
Fresnel-Kirchoff diffraction integral
Unobstructed Obstructed: 50% linear, 25% area
Encircled Energy as a Fraction of the Total Transmitted Light with no aberrations
Fresnel-Kirchoff diffraction integral: Schroeder 10.2
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Linear obstruction = 0%, 10%, 20%, 30%, 40%, 50%
EE50 Radius (arcsec) ComparisonHeld constant: f/11, WFE=0.1µm rms, pixel =18µm, blur= 1µm, ACS blur=0.02 arcsec.
• Results show little difference in the visible since we are not diffraction limited there
• However longward of one micron, diffraction dominates the PSF, and the unobscured looks attractive.
• On the faintest targets, Rhalf hurts you like its square (ouch)
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1.1m obscured
1.3m obscured
1.1m unobscured
1.3m unobscured
Wavelength microns
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Eliminating the SM support spider legs
At Galactic midlatitudes, diffraction rings and spikes bring the focal plane irradiance to twice Zodi over 1% of random locations. Elimination: slightly improved survey efficiency; eases background subtraction, reduced “coverage gap” correlation .
HST file image courtesy STScI
Some Unobscured Concepts
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Mountaintop Solar McMath: Pierce11
NST: Denker et al.12
ATST: Rimmele13
Mountaintop General Astron LAPCAT (proposed): Storey et al14
NPT (proposed): Moretto & Kuhn15
4m DFL (proposed): Moretto & Kuhn16
Spaceborne Remote Sensing MTI: Kay et al.17
TopSat: Price18
QuickBird: Figoski19
EO-1 ALI: Lencione et al20
CartoSat: Subrahmanyam et al21
Spaceborne Stellar GAIA: Perryman22
DIVA (proposed): Graue et al23
Spaceborne Planet Search JPF (proposed): Krist et al24
TPF (proposed): Noecker25
ECLIPSE (proposed): Trauger et al26, Hull et al27
Manufacturing & Testing Challenges?• Off-axis: more material removal and greater aspheric departure• Off-axis: non axisymmetric test setups need more time & care• Existence proof: Giant Magellan Telescope segments: 8.4m!• Today’s laser trackers can deliver submicron surface metrology• Vendors caution us that going off-axis is do-able but not “free”
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-500 0 500 1000 15000
0.1
0.2
0.3
0.4
0.5
Radius from optical axis (mm)
Asp
heric
Dep
artu
re (m
m)
Aspheric Departure of 1.1m f/11 On-axis and Off-axis TMA Primary Mirror
On-axis TelescopeOff-axis Telescope
Payload Packaging Challenges?
• Traditional space telescope payloads are on-axis cylinders• Traditionally the launch fairing is a cylinder plus an ogive
extension• Good match!• Off-axis telescope is not a good match• However … going to Earth-Sun L2 Lagrange point requires an
EELV whose launch fairing is 4m diameter. Plenty of room for any layout of a 1.1 m aperture telescope
• As presently envisioned, JDEM packaging is not constrained by EELV fairing, even though off axis
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Many JDEM Trade Studies RemainContent et al.; Sholl et al.; Lieber et al.; Noecker; Edelstein et al.; Besuner et al.; Reil et al.
• Focal vs Afocal rear-end architecture• Imager requirements and design
– Field of view; plate scale; pixel size; waveband(s)…– How to calibrate it: flats, darks, wavelength, linearity…
• Wide field spectrometer requirements– Field of view; plate scale; pixel size; waveband…– Resolving power; issue of redshift accuracy.– How to calibrate it: flats, darks, wavelength, linearity…
• Supernova spectrometer requirements– Single slit vs integral field slicer architecture– Field of view; plate scale; pixel size; waveband– How to calibrate it: flats, darks, wavelength, linearity…
• The overall mission design: how to best integrate objectives• And then… of course … there’s all the engineering!
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Obscured Unobscured• Traditional in space astronomy• Axisymmetric PM has lower
manufacture & test cost for given aperture because total departure from sphere is less
• If Wide field: SM baffle is large then there is appreciable light loss from SM blockage of the pupil
• Diffraction by SM: a concern• Scattering by SM support spiderlegs:
an annoyance, esp for WL• Spider leg flex can contribute to
resonances that influence PSF
• Unobscured space telescopes are employed for terrestrial remote sensing (DoE M.T.I.) with severe requirements on stray light
• Superior MTF, PSF, and EE nearly equal to ideal Airy pattern
• Industry lacks flight mirror experience in sizes above 0.6m => higher risk and potentially higher fab cost
• Potentially reduced stray light, stray heat => tiny risk reduction and possibly more thorough testing
• Potentially a stiffer, stronger structure: no spider legs
Decision: to be based on benefits, cost, and risk assessment
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Conclusions
• At λ>1µm, pupil obstruction is a concern– Diffraction dominates the PSF and EE– PSF and EE influence science return– S/N ratio is major driver on Texp, aperture, FoV.– BAO team seeks a high survey rate in the NIR– WL team seeks a high survey rate and a high density of resolved
galaxies, which is very sensitive to PSF growth– SN team seeks high S/N spectroscopy at highest redshifts
• Unobstructed pupil improves performance in all these areas
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Backups
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Dark Energy• Our observed universe: expanding, accelerating, lumpy
– Hubble: and many many others: expanding! H(0)– COBE , WMAP: warm, isotropic, shows primordial structure– Perlmutter et al; Riess et al.: SNe, standard candles: accelerating! H(z)– Eisenstein et al; Cole et al.; structure; standard rulers: BAO => H(z)
• Explanations– Einstein (1917) General Relativity: geometry; many tests tried and passed– Many alternative theories are out there
• If GR is correct… Ωm + Ωk + ΩΛ = 1– Empirically today… 0.27 + 0 + 0.73 ≈ 1
• …But there are puzzling aspects of this!– What is Λ? Physics offers no answer.– Why is Ωm ~ ΩΛ today, i.e. why now?
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Physical baryon density Ωb Physical CDM density Ωc Physical DE density ΩΛ
Scalar curvature Δ2R
Spectral index ns
Reionization optical depth τ
SIX PARAMETER FLAT ΛCDM
Committees & Reports
• Dark Energy Task Force– Albrecht et al., Sept 2006– http://www.nsf.gov/mps/ast/aaac/dark_energy_task_force/
• Figure Of Merit Science Working Group– Albrecht et al., Dec 2008– http://jdem.gsfc.nasa.gov/
• JDEM Science Coordination Group– Gehrels, April 2009– http://jdem.gsfc.nasa.gov/
• Interim Science Working Group– Moos & Baltay (co-chairs) May 2010– http://jdem.lbl.gov/
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DETF Recommendations http://www.NSF.gov/mps/ast/detf.jsp (2006)
• Recommended that multiple techniques be pursued• Baryon Acoustic Oscillations: less affected by astrophysical
uncertainties than other methods, but presently less proven• Supernovae: presently is most powerful & best proven; but
systematics will depend on astronomical flux calibration• Weak Lensing: emerging technique; may become the most
powerful technique in constraining dark energy.• Clusters: good statistical potential; but presently has largest
systematic errors.
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“… For these reasons, the nature of dark energy ranks among the very most compelling of all outstanding problems in physical science. These circumstances demand an ambitious observational program to determine the dark energy properties as well as possible.”
BAO: Requirements & Implementation• Require: redshift range 1.3<z<2.0• Survey 16000 sq degrees of sky• Identify emission line galaxies by the Hα
line feature, and/or other lines• Sample faint enough to reach ~2E-16
erg/cm2sec line flux• Yields about 1 galaxy /sq arcmin• Yields about 50 million galaxies• Required accuracy σz = 0.001/(1+z)
• Plan: slitless spectrometer with a wide FoV ~ 0.5 square degree
• Span wavelengths 1.5µm<λ< 2.0µm• Exposure time ~ 1ksec/field• 32000 spectro fields + cal fields
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http://jdem.lbl.gov/ “Rolling Disperser”
Type Ia Supernovae: standard candles• “SD” model: Whelan & Iben (1973)• WD accretes matter from a binary companion• Carbon or oxygen white dwarf star; no H or He• WD mass reaches 1.38 Msun =
– Radius begins shrinking rapidly– Gravitational energy = -1E44 joule = -1 “foe”
• It will heat and collapse. Fusion ensues…• 12C→24Mg →56Ni →56Co →56Fe + 0.12% Mc2
– If 67% efficient: 2E44 joule = +2 foe• Annihilates the WD star!• Roughly 1E44 joules remain for KE & light• Good uniformity: calibrated standard candles• Measure each peak brightness and redshift• Fit the observed SNe to a distance modulus curve• Each DE model predicts a distance modulus curve• So… compare these to constrain models.
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Kowalski et al., ApJ 686, 749 (2008)
Supernova Program Requirements• Quantity of Supernovae for statistics
– Span the redshift range 0.2<z<1.5– Discover and analyze about 100 SNe per redshift bin Δz=0.1– Use ~ four day cadence revisiting discovery fields, two wavebands
• Diagnostic spectra and fluxes throughout light curve for systematics– “Onion peeling” to detect unusual changes in colors for subclassification– Approx 12 lightcurve spectra on a four day cadence in SN restframe– Near peak, one deep precise spectrum with R1pixel = 100, SNR/pix = 17 @ Si II– Accuracy: error of a few percent per supernova is OK…..– But relative systematic flux error over redshift should be less than 1%– One or more reference spectra post-supernova for subtraction
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explosion
Peak spectrum
Reference spectrum
Figure courtesy A.G.Kim 2010
Off-peak spectra
• Discovery Phase: repeatedly visit tiered survey fields with a two-filter imager– Nearby SNe: short exposures, broad field
~ 10 sqdeg, large A∙– Distant SNe: long exposures, smaller
field ~ 1.6 sqdeg, small A∙– Efficient! <10% of SN program time– Can reject some Type II supernovae
• Spectroscopy Phase: revisit with dedicated spectrometer, R>100– Early rejection of Type II SNe from first
few spectra: presence of hydrogen– Subclassification of Type Ia’s using
synthetic photometry lightcurve – Detailed subclassification near peak – Also gives host galaxy redshift
Supernova Program Implementation
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Top curve: deep spectrum SNR taken near peak light, z=1.2; nominal Texp.
Lower curves: short exposure SNRs before and after peak; sufficient SNR for broad “UBVRI” colors, and no K-correction required for fixed filter edges & responses. Nominal Texp. Figure courtesy A.G.Kim 2010.
Supernova Redshift Range & Model ConstraintsFigures 1, 2 from Kent et al. arXiv 0903.2799 (2009)
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WL: Requirements & Implementation• Requires a dense survey: 30 galaxies per
square arcminute• Translates to ABmag ~ 25• Requires a wide survey: > 10000 square
degrees• Requires good PSF: e.g. 0.2 arcsec pixels • Requires Photo-Z grade redshifts • That in turn means an associated redshift
calibration program
• Plan: Wide Field Imager, ~ 0.5 sqdeg• Texposure ~ few kiloseconds• 20000 frames, with 4x dithering• Use stars in each frame for instrumental
PSF map and shear calibration
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Jouvel et al., “Designing Future Dark Energy Missions” A&A 504, 359 (2009)
Rhalf, arcseconds
Supernovae, BAO, and CMB constrain the equation of state of the Universe
current (2010) data constraints
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Equation of state w = p/ρ
For a cold gas or nonrelativistic fluid, w = 0
For a DE dominated Λ universe, w = -1
Then … w is a key diagnostic of the universe and the prevalence of dark energy, including its evolution over cosmic time.
BAO Emission-Line Galaxy SizesSchlegel & Mostek “Exposure Time Requirements for JDEM BAO Measurements” 3 Dec 2008
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Survey Rate for simplest caseContinuum target, Diffuse background
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2half
2
2min
R πAEFFoV
BSNRΔλN0.25 RateSurvey
Nmin = minimum needed continuum photon fluxSNR = required signal to noise ratioB = diffuse sky continuum levelFoV = imager survey area on skyA = telescope light gathering areaE = system throughput efficiencyF = fraction of time allocated Δλ = wavelength bandpassRhalf = half light radius of target image
To maximize survey rate: maximize that last group of factors, and of course minimize the half light radius of the faintest images.
This talk
JSIM http://jdem.lbl.gov/ “Exposure Time Calculator”
• Public web-based tool created by M.Levi with Project Office inputs• Inputs are high-level mission parameters
– Telescope Aperture, central obstruction size, WFE…– Field of view on sky, pixel scale, focal length, number of sensor chips– Detector Technology: pixel size, pixels per chip, waveband, QE curve– Fraction of time allocated to BAO, SNe, WL, calibration, downlink, … – Mission duration
• Also low-level inputs for sensors, filter bandwidths, etc• Outputs are available at “high level” i.e. productivity yield measures
per year of operations for a given objective and figures-of-merit scaled from comparisons with DETF estimates
• Also “low level” outputs, decomposing yield into redshift bins, for estimating individual cosmological parameter constraints
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JSIM Primary Mission Input Parameters http://jdem.lbl.gov/ “Exposure Time Calculator”
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JSIM Summary Output Results http://jdem.lbl.gov/ “Exposure Time Calculator”
• Gives both broad & detailed predictions of a JDEM design• Confirms the notion that shrinking Rhalf boosts performance• Roughly, 1.1m unobscured aperture ≈ 1.4m 50% obscured
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