Euclid: ESA's mission to map the geometry of the dark universe

Laureijs, R. J.; Gondoin, P.; Duvet, L.; Criado, Gonzalo Saavedra; Hoar, J.; Amiaux, J.; Auguères, J.-L.; Cole, Richard E.; Cropper, Mark; Ealet, A.; Ferruit, Pierre; Sanz, I. Escudero; Jahnke, K.; Kohley, R.; Maciaszek, T.; Mellier, Y.; Oosterbroek, T.; Pasian, F.; Sauvage, M.; Scaramella, R.; Sirianni, M.; Valenziano, L.

doi:10.1117/12.926496

Cited by 176 publications

(194 citation statements)

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“…While BigBOSS, Euclid, and WFIRST all plan to measure BAO in the range 1 < z < 2, it is not clear that they can achieve f sky = 0.25 with nP ≈ 2 even collectively. Euclid plans to survey ≈ 14, 000 deg 2 over the range 0.7 < z < 2 in its 6.25-year primary mission, but the forecasts in Green et al (2012), which are based on the Euclid instrument sensitivity of Laureijs et al (2011) and the Hα luminosity function and galaxy bias measurements of Sobral et al (2013) and Geach et al (2012), imply that Euclid will reach nP < 0.5 at z > 1.2. BigBOSS plans to survey 14, 000 deg 2 in the northern hemisphere, and a southern hemisphere equivalent could increase the area to 24, 000 deg 2 (limited in the end by Galactic extinction).…”

Section: Observables and Aggregate Precisionmentioning

confidence: 99%

“…Current incarnations of these plans are described in the Euclid Red Book (Laureijs et al, 2011) and the WFIRST Science Definition Team's final report (Green et al, 2012), though technical specifications and survey strategies may evolve to some degree prior to launch. The present baseline strategy for Euclid has a a survey area of approximately 14,000 deg 2 and redshift range 0.7 < z < 2.0, while the baseline strategy for WFIRST adopts a smaller area (3,400 deg 2 ), fainter flux limit, and higher redshift range (1.3 < z < 2.7).…”

Section: Prospectsmentioning

confidence: 99%

“…Euclid plans to carry out optical and near-IR imaging and near-IR slitless spectroscopy over roughly 14,000 deg 2 , for weak lensing and BAO measurements. In its current design (Laureijs et al, 2011), Euclid utilizes a 1.2-meter telescope, a 0.56 deg 2 optical focal plane (604 million 0.10 ′′ pixels), and a near-IR focal plane with similar area but larger pixels (67 million 0.30 ′′ pixels). Well ahead of either Euclid or WFIRST, the European X-ray telescope eROSITA (on the Russian Spectrum Roentgen Gamma satellite) is expected to produce an all-sky catalog of ∼ 10 5 X-ray selected clusters, with X-ray temperature measurements and resolved profiles for the brighter clusters (Merloni et al, 2012).…”

Section: Looking Forwardmentioning

confidence: 99%

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Observational probes of cosmic acceleration

et al. 2013

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The accelerating expansion of the universe is the most surprising cosmological discovery in many decades, implying that the universe is dominated by some form of "dark energy" with exotic physical properties, or that Einstein's theory of gravity breaks down on cosmological scales. The profound implications of cosmic acceleration have inspired ambitious efforts to understand its origin, with experiments that aim to measure the history of expansion and growth of structure with percent-level precision or higher. We review in detail the four most well established methods for making such measurements: Type Ia supernovae, baryon acoustic oscillations (BAO), weak gravitational lensing, and the abundance of galaxy clusters. We pay particular attention to the systematic uncertainties in these techniques and to strategies for controlling them at the level needed to exploit "Stage IV" dark energy facilities such as BigBOSS, LSST, Euclid, and WFIRST. We briefly review a number of other approaches including redshift-space distortions, the Alcock-Paczynski effect, and direct measurements of the Hubble constant H 0 . We present extensive forecasts for constraints on the dark energy equation of state and parameterized deviations from General Relativity, achievable with Stage III and Stage IV experimental programs that incorporate supernovae, BAO, weak lensing, and cosmic microwave background data. We also show the level of precision required for clusters or other methods to provide constraints competitive with those of these fiducial programs. We emphasize the value of a balanced program that employs several of the most powerful methods in combination, both to cross-check systematic uncertainties and to take advantage of complementary information. Surveys to probe cosmic acceleration produce data sets that support a wide range of scientific investigations, and they continue the longstanding astronomical tradition of mapping the universe in ever greater detail over ever larger scales.

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Section: Observables and Aggregate Precisionmentioning

confidence: 99%

Section: Prospectsmentioning

confidence: 99%

Section: Looking Forwardmentioning

confidence: 99%

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Observational probes of cosmic acceleration

et al. 2013

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“…Looking beyond these ground-based surveys, the ESA Euclid mission, with a nominal launch date of 2019, will revolutionise observational cosmology by conducting imaging and spectroscopic surveys that are approximately two orders of magnitude better than those currently available (Laureijs et al 2011). …”

Section: -20 Years Timementioning

confidence: 99%

Large-scale structure observations

Percival¹

2015

Post-Planck Cosmology

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“…SLCs are now well established as a promising class of objects that cannot be ignored in cosmology, and their future is extremely promising, since future facilities are expected to detect thousands of SLCs (Laureijs et al 2011;Boldrin et al 2012Boldrin et al , 2016Serjeant 2014), and the exquisite resolution of the James Webb Space Telescope (JWST) will deliver unique multi-colour data sets for some of them. The growing importance of SLCs has been recently illustrated by the CLASH program (Postman et al 2012) which has been awarded of 500 HST orbits to observe 25 massive SLCs.…”

Section: Introductionmentioning

confidence: 99%

Characterizing strong lensing galaxy clusters using the Millennium-XXL and moka simulations

Giocoli¹,

Bonamigo²,

Limousin³

et al. 2016

Mon. Not. R. Astron. Soc.

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In this paper we investigate the strong lensing statistics in galaxy clusters. We extract dark matter haloes from the Millennium-XXL simulation, compute their Einstein radius distribution, and find a very good agreement with Monte Carlo predictions produced with the MOKA code. The distribution of the Einstein radii is well described by a log-normal distribution, with a considerable fraction of the largest systems boosted by different projection effects. We discuss the importance of substructures and triaxiality in shaping the size of the critical lines for cluster size haloes. We then model and interpret the different deviations, accounting for the presence of a Bright Central Galaxy (BCG) and two different stellar mass density profiles. We present scaling relations between weak lensing quantities and the size of the Einstein radii. Finally we discuss how sensible is the distribution of the Einstein radii on the cosmological parameters Ω M − σ 8 finding that cosmologies with higher Ω M and σ 8 possess a large sample of strong lensing clusters. The Einstein radius distribution may help distinguish Planck13 and WMAP7 cosmology at 3σ.

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Euclid: ESA's mission to map the geometry of the dark universe

Cited by 176 publications

References 4 publications

Observational probes of cosmic acceleration

Observational probes of cosmic acceleration

Large-scale structure observations

Characterizing strong lensing galaxy clusters using the Millennium-XXL and moka simulations

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