“The Dark SDSS” Bob Nichol ICG, Portsmouth Special thanks to Masao Sako, David Weinberg, Andy Connolly, Albert Stebbins, Rob Crittenden, Daniel Eisenstein,

Slides:

Advertisements

Similar presentations

Seeing Dark Energy (or the cosmological constant which is the simplest form of DE) Professor Bob Nichol (ICG, Portsmouth)

Advertisements

Observing Dark Energy SDSS, DES, WFMOS teams. Understanding Dark Energy No compelling theory, must be observational driven We can make progress on questions:

Weighing Neutrinos including the Largest Photometric Galaxy Survey: MegaZ DR7 Moriond 2010Shaun Thomas: UCL “A combined constraint on the Neutrinos” Arxiv:

UCL’s interests: photo-z, mass-obs calibration, systematics Granada, Sep 2010 Ofer Lahav, University College London Ofer Lahav, Stephanie Jouvel, Ole Host.

Photo-z for LRGs, DES, DUNE and the cross talk with Dark Energy Ofer Lahav, University College London 1. The Dark Energy Survey 2. Photo-z methodology.

“The Dark Side of the SDSS” Bob Nichol ICG, Portsmouth Chris Miller, David Wake, Brice Menard, Idit Zehavi, Ryan Scranton, Gordon Richards, Daniel Eisenstein,

Cosmological Constraints from Baryonic Acoustic Oscillations

What Figure of Merit Should We Use to Evaluate Dark Energy Projects? Yun Wang Yun Wang STScI Dark Energy Symposium STScI Dark Energy Symposium May 6, 2008.

Optimization of large-scale surveys to probe the DE David Parkinson University of Sussex Prospects and Principles for Probing the Problematic Propulsion.

CMB: Sound Waves in the Early Universe Before recombination: Universe is ionized. Photons provide enormous pressure and restoring force. Photon-baryon.

SDSS-II SN survey: Constraining Dark Energy with intermediate- redshift probes Hubert Lampeitl University Portsmouth, ICG In collaboration with: H.J. Seo,

Observational Cosmology - a laboratory for fundamental physics MPI-K, Heidelberg Marek Kowalski.

Massive Spectroscopy for Dark Energy in the South Josh Frieman MS-DESI Meeting, LBNL, March 2013 Some details in DESpec White Paper arXiv: (Abdalla,

The National Science Foundation The Dark Energy Survey J. Frieman, M. Becker, J. Carlstrom, M. Gladders, W. Hu, R. Kessler, B. Koester, A. Kravtsov, for.

Lecture 2: Observational constraints on dark energy Shinji Tsujikawa (Tokyo University of Science)

Nikolaos Nikoloudakis Friday lunch talk 12/6/09 Supported by a Marie Curie Early Stage Training Fellowship.

July 7, 2008SLAC Annual Program ReviewPage 1 Future Dark Energy Surveys R. Wechsler Assistant Professor KIPAC.

Dark Energy with 3D Cosmic Shear Dark Energy with 3D Cosmic Shear Alan Heavens Institute for Astronomy University of Edinburgh UK with Tom Kitching, Patricia.

Cosmology with Spectroscopic and Photometric Redshift Surveys Ofer Lahav Department of Physics and Astronomy University College London The post-2dF/SDSS/WMAP3.

Dark Energy J. Frieman: Overview 30 A. Kim: Supernovae 30 B. Jain: Weak Lensing 30 M. White: Baryon Acoustic Oscillations 30 P5, SLAC, Feb. 22, 2008.

Nikos Nikoloudakis and T.Shanks, R.Sharples 9 th Hellenic Astronomical Conference Athens, Greece September 20-24, 2009.

1 SDSS-II Supernova Survey Josh Frieman Leopoldina Dark Energy Conference October 8, 2008 See also: poster by Hubert Lampeitl, talk by Bob Nichol.

Clustering of Luminous Red Galaxies and Applications to Cosmology NicRoss (Penn State) Research Progress Meeting LBNL 8th November 2007 Ross et al., 2007,

The Science Case for the Dark Energy Survey James Annis For the DES Collaboration.

Daniel Eisenstein – Univ. of Arizona WFMOS Bob Nichol on behalf of the WFMOS/KAOS collaborations (see Thanks to Matthew Colless,

NAOKI YASUDA, MAMORU DOI (UTOKYO), AND TOMOKI MOROKUMA (NAOJ) SN Survey with HSC.

“Observing Dark Energy” Bob Nichol ICG, Portsmouth Special thanks to Masao Sako, David Weinberg, Andy Connolly, Albert Stebbins, Rob Crittenden, Daniel.

Polarization-assisted WMAP-NVSS Cross Correlation Collaborators: K-W Ng(IoP, AS) Ue-Li Pen (CITA) Guo Chin Liu (ASIAA)

Studying Cosmic acceleration and neutrino masses with DES. Studying Cosmic acceleration and neutrino masses with DES.

Dark energy I : Observational constraints Shinji Tsujikawa (Tokyo University of Science)

Cosmic Structures: Challenges for Astro-Statistics Ofer Lahav Department of Physics and Astronomy University College London * Data compression – e.g. P(k)

“The Dark Side of the SDSS” Bob Nichol ICG, Portsmouth Thanks to all my collaborators on SDSS and other teams.

Constraints on Dark Energy from CMB Eiichiro Komatsu University of Texas at Austin Dark Energy February 27, 2006.

Constraining the Dark Side of the Universe J AIYUL Y OO D EPARTMENT OF A STRONOMY, T HE O HIO S TATE U NIVERSITY Berkeley Cosmology Group, U. C. Berkeley,

1 SDSS Supernova Survey Josh Frieman Supernova Rates 2008, Florence May 19, 2008.

Observational test of modified gravity models with future imaging surveys Kazuhiro Yamamoto (Hiroshima U.) Edinburgh Oct K.Y. ， Bassett, Nichol,

Clustering in the Sloan Digital Sky Survey Bob Nichol (ICG, Portsmouth) Many SDSS Colleagues.

Dark Energy Probes with DES (focus on cosmology) Seokcheon Lee (KIAS) Feb Section : Survey Science III.

Dark Energy & LSS SDSS & DES teams (Bob Nichol, ICG Portsmouth) Marie Curie (EC)

PHY306 1 Modern cosmology 4: The cosmic microwave background Expectations Experiments: from COBE to Planck  COBE  ground-based experiments  WMAP  Planck.

WFMOS KAOS concept identified via the Gemini Aspen Process and completed a Feasibility Study (Barden et al.) Proposed MOS on Subaru via an international.

What’s going on with Dark Energy? Bill Carithers Aspen 2008.

David Weinberg, Ohio State University Dept. of Astronomy and CCAPP The Cosmological Content of Galaxy Redshift Surveys or Why are FoMs all over the map?

A. Ealet, S. Escoffier, D. Fouchez, F. Henry-Couannier, S. Kermiche, C. Tao, A. Tilquin September 2012.

Using Baryon Acoustic Oscillations to test Dark Energy Will Percival The University of Portsmouth (including work as part of 2dFGRS and SDSS collaborations)

Wiggles and Bangs SDSS, DES, WFMOS teams. Understanding Dark Energy No compelling theory, must be observational driven We can make progress on questions:

Type Ia Supernovae and the Acceleration of the Universe: Results from the ESSENCE Supernova Survey Kevin Krisciunas, 5 April 2008.

Dark Energy and Cosmic Sound Daniel Eisenstein Steward Observatory Eisenstein 2003 (astro-ph/ ) Seo & Eisenstein, ApJ, 598, 720 (2003) Blake & Glazebrook.

BAOs SDSS, DES, WFMOS teams (Bob Nichol, ICG Portsmouth)

Cosmic shear and intrinsic alignments Rachel Mandelbaum April 2, 2007 Collaborators: Christopher Hirata (IAS), Mustapha Ishak (UT Dallas), Uros Seljak.

Will Percival The University of Portsmouth

SDSS II Supernova Survey - The Science Wednesday 29th August 2007 DARK Summer Institute Mathew Smith In collaboration with B. Nichol (ICG) and the SDSS.

The Feasibility of Constraining Dark Energy Using LAMOST Redshift Survey L.Sun.

Latest Results from LSS & BAO Observations Will Percival University of Portsmouth StSci Spring Symposium: A Decade of Dark Energy, May 7 th 2008.

Searching High-z Supernovae with HSC and WFMOS

Cosmology with ESO telescopes Bruno Leibundgut. Outline Past and current cosmology projects with ESO telescopes Future instrumentation capabilities (interferometry?)

The XMM Cluster Survey: Project summary and Cosmology Forecasts Kathy Romer University of Sussex.

Observational evidence for Dark Energy

Future observational prospects for dark energy Roberto Trotta Oxford Astrophysics & Royal Astronomical Society.

BAO,ISW+SZ from AA  +SDSS R.M. Bielby, U. Sawangwit, T. Shanks, Durham University + 2SLAQ + AAOmega teams.

1 SDSS-II Supernova Survey Josh Frieman SDSS Science Symposium August 18, 2008.

Two useful methods for the supernova cosmologist: (1) Including CMB constraints by using the CMB shift parameters (2) A model-independent photometric redshift.

Brenna Flaugher for the DES Collaboration; DPF Meeting August 27, 2004 Riverside,CA Fermilab, U Illinois, U Chicago, LBNL, CTIO/NOAO 1 Dark Energy and.

Probing Dark Energy with Cosmological Observations Fan, Zuhui ( 范祖辉 ) Dept. of Astronomy Peking University.

“The Dark Side of the SDSS” Bob Nichol ICG, Portsmouth Thanks to all my collaborators on SDSS and other teams.

Carlos Hernández-Monteagudo CE F CA 1 CENTRO DE ESTUDIOS DE FÍSICA DEL COSMOS DE ARAGÓN (CE F CA) J-PAS 10th Collaboration Meeting March 11th 2015 Cosmology.

Jochen Weller Decrypting the Universe Edinburgh, October, 2007 未来の暗黒エネルギー実験の相補性.

The Dark Energy Survey Probe origin of Cosmic Acceleration:

Combining Different Measurements

6-band Survey: ugrizy 320–1050 nm

Presentation transcript:

“The Dark SDSS” Bob Nichol ICG, Portsmouth Special thanks to Masao Sako, David Weinberg, Andy Connolly, Albert Stebbins, Rob Crittenden, Daniel Eisenstein, Josh Frieman, Tom Giannantonio, Ryan Scranton, Will Percival SDSS team

August 1st 2006Durham "Cosmic Frontiers" Outline Dark Energy Primer Dark Energy Primer Growth of Structure: ISW Growth of Structure: ISW Geometry: SN & BAO Geometry: SN & BAO DE measurements in SDSS are close to systematics limited already

August 1st 2006Durham "Cosmic Frontiers" Understanding Dark Energy We can make progress on questions: Is DE just a cosmological constant (w(z)=-1)? (Make better observations and push to higher z) Is DE a new form of matter (with negative effective pressure) or a breakdown of GR? (Study DE using different probes) But there are only two broad avenues: Geometrical tests (SN, BAO) Growth of structure (CL, WL) No compelling theory, so must be observational driven

August 1st 2006Durham "Cosmic Frontiers" DETF Report (Kolb et al) 138 pages condensed to this column SN & BAO - safe, but only 100% improvement CL & WL - risky, but big gains Clear recommendation to do multiple measurement with one being the growth of structure to test GR

August 1st 2006Durham "Cosmic Frontiers" The effect of DE is only seen on large scales, therefore we need to study large volumes to beat “cosmic variance” DE is a small effect (even on large scales) so need large samples to control statistical and systematic errors We need to understand the redshift evolution of DE (w(z)) DE require “big surveys” Challenge to experimentalists to build massive surveys (in size and number) with high precision

August 1st 2006Durham "Cosmic Frontiers" “Massive Surveys” SDSS: first “massive” survey ISW SDSSII SNe Baryon Acoustic Oscillations (BAO) DES: next “massive” imaging survey The power of photo-z’s WFMOS: next “massive” redshift survey The power of spectroscopy

SDSS DR5: Million spectra, 8000 sq degs Extension ( ): Legacy, SNe, Galaxy

August 1st 2006Durham "Cosmic Frontiers" Stage I & II: Growth of Structure

Late-time Integrated Sachs Wolfe (ISW) Effect DE also effects the growth of structure i.e. Poisson equation with dark energy: DE also effects the growth of structure i.e. Poisson equation with dark energy: In a flat, matter-dominated universe (CMB tells us this), then density fluctuations grow as: In a flat, matter-dominated universe (CMB tells us this), then density fluctuations grow as: Therefore, for a flat geometry, changes in the gravitational potential are a direct physical measurement of Dark Energy as they should be non- evolving if DE=0 Therefore, for a flat geometry, changes in the gravitational potential are a direct physical measurement of Dark Energy as they should be non- evolving if DE=0

Experimental Set-up Nolta et al, Boughn & Crittenden, Myers et al, Ashfordi et al, Fosalba et al., Gaztanaga et al., Rassat et al.

WMAP-SDSS cross-correlation WMAP W band Luminous Red Galaxies (LRGs) No signal in a flat, matter dominated Universe

ISW Detected 5300 sq degrees 5300 sq degrees Achromatic Achromatic (no contamination) Upto 5  detection Upto 5  detection Update of Scranton et al. 2003

August 1st 2006Durham "Cosmic Frontiers" Theoretical Predictions W-band z=0.49 LRGs  m =0.3  m =0.2 Degeneracy between b, n(z) and cosmology

August 1st 2006Durham "Cosmic Frontiers" Giannantonio et al (astro-ph/ ) WMAP3-photoQSO WMAP3 best fit Detection of DE at z> <  m < <w<-0.76

August 1st 2006Durham "Cosmic Frontiers" Evolution of DE w=-1 survives another (weak) test But rules out models with  D  (z=1.5) > 0.5 Important for tests of modified gravity theories

August 1st 2006Durham "Cosmic Frontiers" Stage I & II: Geometrical Tests

August 1st 2006Durham "Cosmic Frontiers" bridge low-z (z<0.05; LOSS, SNF) and high-z (0.3<z<1.0; ESSENCE, SNLS) sources bridge low-z (z<0.05; LOSS, SNF) and high-z (0.3<z<1.0; ESSENCE, SNLS) sources understand and minimize systematics of SN Ia as distance indicators (look at correlations with host galaxy properties) understand and minimize systematics of SN Ia as distance indicators (look at correlations with host galaxy properties) SDSSII SNe Survey SDSSII SNe Survey Exploring DE & SNe at an epoch when DE dominates Riess et al. (2004) compilation Astier et al. (2005) 9% measurement of w by 2008 comparable with SNLS 6% measurement of w when combined with SNLS Espana-Bonet, Nichol, Ruiz-Lapuente

August 1st 2006Durham "Cosmic Frontiers" Use the SDSS 2.5m telescope September 1 - November 30 of September 1 - November 30 of Scan 300 square degrees of the sky every 2 days Scan 300 square degrees of the sky every 2 days “Stripe82” (UKIDSS data) “Stripe82” (UKIDSS data) Survey Area NS

August 1st 2006Durham "Cosmic Frontiers" Color-type SNe candidates using nightly g r i data fit light-curve for redshift, extinction, stretch for Ia Able to type with >90% efficiency after ~2 - 4 epochs Photometric Typing Ia II SN2005hy II

August 1st 2006Durham "Cosmic Frontiers" Team of 15 “hand-scanner” visually inspected 144,000 objects selecting nearly 10k SN targets!

August 1st 2006Durham "Cosmic Frontiers" 229 spectroscopically confirmed SN Ia 150 unconfirmed Ia’s with good LC’s (galaxy redshifts exist for 60) Many Ia’s now have multi-epoch spectra Follow-up on NTT, WHT, Subaru (Yasuda et al.), ARC3.5m, HET, MDM = 0.21 Still one more month to go this year (expect 300 by end of 2006) International Follow-up

August 1st 2006Durham "Cosmic Frontiers" Galaxy-SNe Correlations

August 1st 2006Durham "Cosmic Frontiers" 2005 spectroscopically confirmed + probable SN Ia

August 1st 2006Durham "Cosmic Frontiers" dispersion ~ 0.18 mag internal consistency

August 1st 2006Durham "Cosmic Frontiers" BAO 2006 (Percival et al. 2006) WMAP3 SDSS DR5 520k galaxies  m =0.24 best fit WMAP model Miller et al. 2001, Percival et al. 2001, Tegmark et al. 2001, Cole et al. 2005, Eisenstein et al. 2005, Hutsei 2006, Blake et al. 2006, Padmanabhan et al. 2006

August 1st 2006Durham "Cosmic Frontiers" Smooth + sinc function (Blake & Glazebrook 2003)

August 1st 2006Durham "Cosmic Frontiers" One parameter Standard ruler (flat,h=0.73,  b =0.17) Percival et al Best fit  m = % detection (3  )

August 1st 2006Durham "Cosmic Frontiers"  m - h Degeneracy h=0.72±0.08 HST  m =  m h WMAP3  m =  m h 2 WMAP3  m =

August 1st 2006Durham "Cosmic Frontiers" Summary   ISW detected at several redshifts to z~1 and consistent with cosmological constant. Good news for people looking for DE at high z   229 SDSS SNIa’s so far, 400 by 2007 Systematics limited and will deliver w to 6%   BAO have been detected at 3   m =0.256 to 10% from acoustic scale Good news for future BAO experiments

August 1st 2006Durham "Cosmic Frontiers" Future Experiments (Stage III)

August 1st 2006Durham "Cosmic Frontiers" Dark Energy Survey (DES) 5000 sq deg multiband (g,r,i,z) survey of SGP using CTIO Blanco with a new wide-field camera 40 sq deg time domain search for SNe 1. 1.Cluster counts from optical+SPT 2. 2.Weak lensing maps 3. 3.SNe Ia distance measurement study from 2000 Sne I. I.Unable to gain spectroscopic follow-up for all these Sne. Must use photometric classifications and redshifts II. II.Use SDSSII as a “training sample” to prepare for DES 4. 4.Galaxy angular power spectrum for 300 million galaxies I. I.Baryon Acoustic Oscillations from photo-z’s Each will independently constrain the dark energy eqn of state <10% DES on-sky by 2009

The Dark Energy Survey UK Consortium The Dark Energy Survey UK Consortium (I) PPARC funding: O. Lahav (PI), P. Doel, M. Barlow, S. Bridle, S. Viti, J. Weller (UCL), R. Nichol (Portsmouth), G. Efstathiou, R. McMahon, W. Sutherland (Cambridge), J. Peacock (Edinburgh) Submitted a proposal to PPARC in February 2005 requesting £ 1.5 M for the DES optical design. In March 2006, PPARC Council announced that it “will seek participation in DES”. (II) SRIF3 funding: R. Nichol, R. Crittenden, R. Maartens, W. Percival (ICG Portsmouth) K. Romer, A. Liddle (Sussex) Funding the optical glass blanks for the UCL DES optical work These scientists will work together through the UK DES Consortium and are collaborating with the Spanish DES Consortium

August 1st 2006Durham "Cosmic Frontiers" ANNz: Collister & Lahav 2005, Abdalla et al. DES Photo-z’s DES science relies on good photometric estimates of the 300 million expected galaxies Simulated DES Simulated DES+VISTA griz grizJK u-band from VST could remove the low-z errors (ugrizJK)

August 1st 2006Durham "Cosmic Frontiers" Give photo-z’s to z~2 with  < 0.1 BAO improves by 50% with VISTA; 15% error on w just the BAO scale Targets for Gemini, VLT Overlap with CLOVER, SPT DES + VISTA + VST DES + Planck ISW will be better than LSST for non- constant w models (Pogosian et al. 2005)

August 1st 2006Durham "Cosmic Frontiers" WFMOS Proposed MOS on Subaru via an international collaboration of Gemini and Japanese astronomers 1.5deg FOV with 4500 fibres feeding 10 low-res spectrographs and 1 high-res spectrograph First-light in 2013 ~20000 spectra a night (2dfGRS at z~1 in 10 nights) DE science, Galactic archeology, galaxy formation studies and lots of ancillary science from database

August 1st 2006Durham "Cosmic Frontiers" z~1 survey with 2 million galaxies with twice LRG volume 1% accuracy KAOS purple book (Seo, Eisenstein, Blake, Glazebrook) WFMOS will measure w to <4% and dw/dz to <15% Distance Scale

August 1st 2006Durham "Cosmic Frontiers" Testing Modified Gravity DGP LCDM 7  difference Yamamoto et al. 2006

Summary II a) Experiments by 2010 will measure w (constant) to a few %, but that doesn’t mean we understand it! b) Next generation surveys will probe w(z) and start testing “growth of structure” measurements of DE