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Deep Radio continuum surveys With acknowledgements to the Wajarri Yamatji people, the traditional owners of ASKAP land Ray Norris Auckland SKANZ meeting,

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Presentation on theme: "Deep Radio continuum surveys With acknowledgements to the Wajarri Yamatji people, the traditional owners of ASKAP land Ray Norris Auckland SKANZ meeting,"— Presentation transcript:

1 Deep Radio continuum surveys With acknowledgements to the Wajarri Yamatji people, the traditional owners of ASKAP land Ray Norris Auckland SKANZ meeting, 16 Feb 2012

2 Overview Background: Radio continuum surveys Square Kilometre Array (SKA) The South African SKA Pathfinder (Meerkat) The Australian SKA Pathfinder (ASKAP) Mapping the Evolution of the Universe (EMU/MIGHTEE) The SKA PAthfinders Continuum Survey WG (SPACS)

3 Astronomy often works in an “explorer” mode as well as a “Popperian” mode:

4 Using redshift to see back in timeATLAS 2dFGRS Photons get stretched (redshift)

5 Using deep surveys to understand galaxy evolution Find a patch of dark sky free from bright stars, dust clouds, etc Make deep images at several different wavelengths Make a census of all galaxies within it Sequence in age (= redshift) Identify different evolutionary tracks rare but important transitional stages

6 The Hubble Deep Field South

7 Can we do this at radio wavelengths? Because of the increasing sensitivity of radio telescopes, current radio surveys: Can trace cosmic SFR to z>1, and AGNs to z>6 Are unaffected by dust Are most powerful when combined with IR and optical data Can trace the origin and evolution of galaxies over cosmic time

8 ATLAS=Australia Telescope Large Area Survey Slide courtesy Minnie Mao

9 SKA Pathfinders Pioneer potential SKA technology Are powerful science-driven observatories Examples: ASKAP (Australia) MeerKAT (South Africa) LOFAR (Netherlands) Apertif (Netherlands) MWA (Australia) EVLA (USA) eMERLIN (UK) eEVN (Europe)

10 Current major 20cm surveys Limit of conventional radio-telescopes SKA pathfinders

11 Current major 20cm surveys NVSS 75% of sky rms=450μJy EMU 75% of sky rms=10μJy EMU+WODAN 100% of sky Increasing sensitivity Increasing area

12 Deep radio image of 75% of the sky (to declination +30°) Frequency range: 1100-1400 MHz 40 x deeper than NVSS 10 μJy rms across the sky 5 x better resolution than NVSS (10 arcsec) Better sensitivity to extended structures than NVSS Will detect and image ~70 million galaxies at 20cm All data to be processed in pipeline Images, catalogues, cross-IDs, to be placed in public domain Survey starts 2013(?) Total integration time: ~1.5 years ?

13 Complementary radio surveys Westerbork-WODAN using Apertif PAF on Westerbork telescope will achieve similar sensitivity to EMU will observe northern quarter of sky (δ>+30°) well-matched to EMU LOFAR continuum surveys lower frequency covering Northern half(?) of sky valuable because yields spectral index Meerkat-MIGHTEE Potentially deeper over smaller area, but will be limited by confusion until Meerkat Phase II (2016?)

14 Slide courtesy of Minnie Mao ATLAS =Australia Telescope Large Area Survey covers 7 sq deg centred on CDFS and ELAIS-S1 has the same rms sensitivity (10μJy) as EMU has the same resolution (10 arcsec) as EMU expect to catalogue 16000 galaxies Final data release early 2012 using EMU prototype tools

15 Redshift distribution of EMU sources Based on SKADS (Wilman et al; 2006, 2008) =1.1 for SF/SB =1.9 for AGN

16 Cross-identification with other wavelengths Spitzer 3.6μm

17 Cross-Identification for EMU (WG chair: Loretta Dunne, Canterbury Uni) We plan to develop a pipeline to automate cross-IDS using intelligent criteria not simple nearest-neighbour working closely with other survey groups use all available information (probably Bayesian algorithm) Expect to be able to cross-ID 70% of the 70 million objects 20% won’t have optical/IR ID’s What about the remaining 10% (7 million galaxies)?

18 What about the difficult cross-IDs?

19 Science Goals

20 Evolution of SF from z=2 to the present day, using a wavelength unbiased by dust or molecular emission. Evolution of massive black holes how come they arrived so early? How do binary MBH merge? what is their relationship to star-formation? Explore the large-scale structure and cosmological parameters of the Universe. E.g, Independent tests of dark energy models Explore an uncharted region of observational parameter space almost certainly finding new classes of object. Explore Diffuse low-surface-brightness radio objects see the Melanie session yesterday Generate an Atlas of the Galactic Plane – see Tom Franzen talk Create a legacy for surveys at all wavelengths (Herschel, JWST, ALMA, etc) Science Goals

21 To trace the evolution of the dominant star-forming galaxies from z=5 to the present day, using a wavelength unbiased by dust or molecular emission. Science Goal 1: measure SFR, unbiased by dust Will detect about 45 million SF galaxies to z~2 Can stack much higher Can measure SFR unbiased by extinction

22 SFR measurable (5σ) by EMU Arp220 z=2 M82 z=0.4 Milky Way z=0.1 With 45 million SF galaxies, can stack to measure SFR to much higher z HyperLIRG z=4 Measured radio SFR does not need any extinction correction

23 Science goal 2: Trace the evolution of AGN Other questions: How much early activity is obscured from optical views? Can we use trace the evolution of MBH with z? When did the first MBH form? How do binary MBH merge? EMU will detect 25 million AGN, including rare objects, such as high-z AGN composite AGN/SF galaxies galaxies in brief transition phases Norris et al. 2008, arXiv:0804.3998 S 20cm = 9mJy z = 0.932 L 20cm = 4 x 10 25 WHz -1

24 F00183-7111 (ULIRG with L=9.10 12 L o ) Merger of two cool spirals: SB just turned on - AGN just turned on radio jets already at full luminosity, boring out through the dust/gas Almost no sign of this at optica/IR wavelengths see Norris et al. arXiv:1107.3895 20kpc 1 kpc P=6.10 25 W/Hz z=0.327

25 Science Goal 3: Cosmology and Fundamental Physics EMU (70 million galaxies) has fewer objects than DES (300 million) but samples a larger volume => complementary tests EMU

26 Integrated Sachs-Wolfe Effect From http://ifa.hawaii.edu/cosmowave/supervoids/ ~10°

27 Dark Energy See Raccanelli et al. ArXiv 1108.0930 “Current error ellipse” is based on Amanullah et al., 2010, ApJ, 716, 712, plus Planck data

28 Modified Gravity See Raccanelli et al. ArXiv 1108.0930

29 The future - SKA Carilli & Rawlings science book written 8 years ago Much has changed (e.g. much of the stuff in this talk wasn’t there to be discussed 10 years ago!) How much of this talk will still be relevant in 10 years time when SKA starts? Current SKA Pathfinders are pathfinding science as well as technology The questions change, but we find we need the SKA even more!

30 Challenge: difficult to get redshifts, or even optical/IR photometry

31 Solution: “statistical redshifts” Photometric redshifts are poor-mans spectroscopic redshifts Statistical redshifts are poor-mans photometric redshifts. Useful if you want to know the statistical properties of a sample. E.g. median z of EMU is 1.1 select polarised sources=> median z = 1.9 select steep-spectrum polarised source => median z =2+(?) Radio/MIR ratio also correlates with z, so even a K-band non- detection is valauble

32 How to find out more? Join the EMU meeting on Friday: WF 710 (on the 7th floor of the WF building. ) See the EMU description: Norris et al. PASA, 28, 215 (arXiv 1106.3219) Join the EMU collaboration Attend the next meeting of SPARCS (SKA PAthfinders Radio Continuum Survey WG) in Sydney on 30 May - 1 June (see spacs.pbworks.com)

33 SPACS: SKA PAthfinders Continuum Survey WG Coordinating design studies and survey goals for continuum surveys on SKA pathfinders Meerkat, ASKAP, Apertif, LOFAR, EVLA, etc. In process of starting up

34 SPACS membership Ray Norris (ASKAP, Australia ) (chair) Kurt van Heyden (Meerkat, South Africa) Huub Rottgering (LOFAR, The Netherlands) Tom Oosterloo (APERTIF, The Netherlands) Joe Lazio (SKA, USA) Jim Condon (EVLA, USA) Geoff Bower (ATA, USA) Rob Beswick (eMERLIN, UK) + many others (i.e. this is an open group)

35 SPACS Goals Coordinate development of techniques avoid duplication of effort ensure that each project has access to best practice. Hold cross-project discussions of science goals cross-fertilise ideas optimise survey strategies. Coordinate the surveys to maximise area depth location on the sky commensality etc

36 SPACS working groups (TBD) Source extraction Cross identification Separating AGN from SF Galaxies Cosmology Low-surface brightness First face-to-face meeting planned for Feb 2011 in Leiden, NL

37 Conclusion We can get transformational science from SKA Pathfinders We can maximise the science by collaborating, not competing Ultimately this will mean better science from the SKA itself (wherever it is built!)

38 EMU Survey Design Paper (Norris et al., PASA, in press, http://arxiv.org/abs/1106.3219)

39 Western Australia

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