Euclid

1. Euclid A Space Mission to Map the Dark Universe R. Laureijs (ESA), A. Refregier (CEA), A. Cimatti (Univ. Bologna), on behalf of the (growing) Euclid Community Dark Energy - Leopoldina Munich

2. Opportunity • ESAs Cosmic visions programme has selected a dark energy mission as a possible candidate for a launch slot in 2017. • Euclid will address the outstanding questions in cosmology • Nature of the Dark Energy • Nature of the Dark Matter • Initial conditions • Theory of Gravity Dark Energy - Leopoldina Munich

3. Outline • Euclid selection and concept • Science Objectives • Mission • Payload • Status and programmatics Dark Energy - Leopoldina Munich

4. Selection of ESAs Dark Energy Mission • Dark energy is recognized by the ESA Advisory Structure as the most timely and important science topic among the M mission proposals and is therefore recommended as the top priority. • Dark energy was addressed by two Cosmic Visions M proposals: • DUNE(PI: A. Refregier-CEA Saclay) – All sky visible and NIR imaging to observe weak gravitational lensing • SPACE(PI: A. Cimatti – Bologna Univ.) – All sky NIR imaging and spectroscopy to detect baryonic acoustic oscillations patterns • An Advisory Team recommended a concept for a single M-Class Dark Energy Mission Dark Energy - Leopoldina Munich

5. Euclid’s Concept • Named in honour of the pioneer of geometry • Euclid will survey the entire extra-galactic sky (20 000 deg2) to simultaneously measure its two principal dark energy probes: • Weak lensing: • Diffraction limited galaxy shape measurements in one broad visible R/I/Z band.AB=24.5 mag • Redshift determination by Photo-z measurements in 3 NIR bands (Y,J,H) to H(AB)=24 mag, 5σ point source • Baryonic Acoustic Oscillations: • Spectroscopic redshift survey for 33% of all galaxies brighter than H(AB)=22 mag, σz<0.001 • With constraints: • Aperture: max 1.2 m diameter • Limited number of NIR detectors • Mission duration: max ~5 years Dark Energy - Leopoldina Munich

6. space weak lensing shear ground WL: shear measurement Typical cosmic shear is ~ 1%, and must be measured with high accuracy In Space: availability of small and stable PSF: larger number of resolved galaxies  reduced systematics Dark Energy - Leopoldina Munich

7. WL: Obtaining NIR photometric redshifts OPT+IR OPT zphoto zspec zspec Abdalla et al. • Will need redshifts for 109 galaxies − photo-z error possible to ~5% in combination with ground-based Pan-Starrs survey etc. • But need 1-2 micron IR for z >1 − impossible from ground (sky brightness) • Need >105 spectroscopic redshifts for calibration Dark Energy - Leopoldina Munich

8. NIR Spectroscopy: DMD based multi-object slit spectroscopy DMD= Digital Micro-mirror Device Dark Energy - Leopoldina Munich

9. Euclid’s Primary Science Objectives Dark Energy - Leopoldina Munich

10. Other Probes • Besides its two principal dark energy probes, Euclid will obtain information of: • Galaxy clustering: the full power spectrum P(k) • Determination of the expansion history and the growth factor using all available information in the amplitude and shape of P(k) • Redshift-space distortions: • Measures the growth rate (derivative of growth factor) from the redshift distortions produced by peculiar motions. • Number density of clusters • Measures a combination of of growth factor (from number of clusters) and expansion history (from volume evolution). • Integrated Sachs-Wolfe Effect • Measures the expansion history and the growth. Dark Energy - Leopoldina Munich

11. Why is the combined mission so powerful High precision and accurate DE measurements require a combination of two or more probes. Euclid aims at the most promising dark energy probes: an all sky survey of weak lensing and galaxy redshifts. • The weak lensing will reconstruct directly the distribution of the dark matter and the evolution of the growth rate of dark matter perturbations with redshift. • The baryon acoustic oscillations act as standard rods,determine P(k) and provide a measure of H(z) and hence w(z). They also map out the evolution of the baryonic component of the Universe. • Together, these enable many systematic effects to be controlled – for example, intrinsic alignments in weak lensing, bias factors in baryon acoustic oscillations. • Both act as independent dark energy probes. If they differ, we learn about modifications to GR. Dark Energy - Leopoldina Munich

12. Predicted redshift dependence of w(z) errors Planck prior is used. The errors are calculated using Fisher matrices using a w(a)=w0+(1-a)wa model, hence the caveat that the errors shown here are correlated (from J. Weller). Dark Energy - Leopoldina Munich

13. Euclid’s Legacy • Visible/NIR imaging survey: morphologies and vis/NIR colors for billions of galaxies out to z~2, 3D dark matter map • Spectroscopic survey: 3D map of the luminous matter distribution, spectra of ~200 million galaxies to z~2 • Deep survey: infrared imaging to H(AB)=26 and spectroscopy to H(AB)=24, galaxies with 2<z<7. Objects at z>7 and up to z~10 can be colour-selected from the Y,J,H colours  Impossible to reach from the ground Dark Energy - Leopoldina Munich

14. Mission profile (1) CDF study case Launcher SOYUZ ST 2-1b from Kourou Launch mass margin: 28% Sky coverage 20 000 sq. degrees extragalactic sky Two galactic polar caps, latitudeb> 30° Solar aspect angle adjusted for scan optimisation Dark Energy - Leopoldina Munich

15. Mission profile (2) Orbit Large amplitude Lissajous around SEL2 Free insertion, 30-day transfer time DeltaV budget: 50 m/s Orbit maintenance: 1 manoeuvre/month First Assessment: All mission elements are standard and feasible Spacecraft Body-mounted solar array, 3-axis stabilised platform Relative pointing error: 25 marcsec with FGS Attitude control with proportional cold gas system Hydrazine propulsion for orbit manoeuvres Satellite mass (wet): 1540 kg Communications Housekeeping in X-band, Science telemetry in K-band 700 Gbits/day after compression 4 hours/day link with Cebreros 35-m antenna Mission duration: 5 years including commissioning Dark Energy - Leopoldina Munich

16. Payload (1) Telescope 1.2 meter Korsch TMA Thermal Passive cooling CCDs at T=170 K NIR detectors at T=140 K Power One power conditioning unit per instrument Total payload: ~200 W peak Data-handling Spectroscopy target selection Full frame images lossless compression NIR detectors noise reduction Dark Energy - Leopoldina Munich

17. NIS NIP VIS Payload (2) 3 instruments Visible Imaging VIS: 0.21” PSF at 800 nm, 0.1”/pixel NIR Photometry NIP: 0.33”/pixel, 3 bands (Y, J, H) NIR Spectroscopy NIS: 0.9-1.7 m, set of 3 cameras, multi-objects (micro-mirror array), R~400 Each of them with a field of view ~0.48 deg2 • Observation mode • Step and stare case fully investigated • Continuous scanning requires a de-scan mechanism for infrared channels Payload mass ~660 kg, including 300 kg for the 3 instruments First Assessment: High technological readiness with some level of complexity Dark Energy - Leopoldina Munich

18. Status and programmatics • Two independent industrial studies have started on the system (including mission and payload): 1 year study until Sep 2009 • Two payload consortia: • Euclid Imaging Channels (EIC),headed by A. Refregier (CEA, France) • Euclid Near-Infrared Spectrometer (ENIS), headed by A. Cimatti (Univ Bologna, Italy) 10 month study until Aug 2009 • DMD flight qualification study started • Overall coordination by ESA and the Science Study Team • Down selection in 2009 • Definition phase 2010-2012 • Implementation phase 2012-2017 Dark Energy - Leopoldina Munich