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WISE - the Wide-field Infrared Survey Explorer

WISE - the Wide-field Infrared Survey Explorer. Ned Wright (UCLA). Project Overview. W ide Field I nfrared S urvey E xplorer. Science Sensitive all sky survey with 8X redundancy Find the most luminous galaxies in the universe Find the closest stars to the sun

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WISE - the Wide-field Infrared Survey Explorer

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  1. WISE - the Wide-field Infrared Survey Explorer Ned Wright (UCLA)

  2. Project Overview Wide Field Infrared Survey Explorer • Science • Sensitive all sky survey with 8X redundancy • Find the most luminous galaxies in the universe • Find the closest stars to the sun • Provide an important catalog for JWST • Provide lasting research legacy • Salient Features • 4 imaging channels covering 3 - 25 microns wavelength • 40 cm telescope operating at <17K • Two stage solid hydrogen cryostat • Delta launch from WTR: 14 Dec 2009 • Sun-synchronous 6am 530km orbit • Scan mirror provides efficient mapping • Expected life: 10 months, actual 7.7-9.5 • 4 TDRSS tracks per day

  3. Infrared • Optical Near-IR Thermal-IR • Reflected light different colors emitted radiation

  4. Space vs Ground • Space hardware costs 1000x more than ground-based. • A huge advantage over ground-based instruments is needed to get funded. • The 1600:1 background ratio was not enough to sell NIRAS in 1988 • 2.7 million to one ratio was sufficient to sell Spitzer and WISE

  5. NIRAS in 1988 • NIRAS SMEX proposal in 1988. Fazio as PI. CJL & ELW as co-I’s. • “Big” Arrays: 58x62 • Constant inertial rate • Scan mirror to freeze images on arrays • All-sky survey at 1.9 and 3.5 μm • Review panel suggested ground-based survey. • NIRAS was not funded! • But this suggestion led to 2MASS • Bottom Line: near-IR only in space will not be an easy sell! • Mid-IR like WISE is sellable.

  6. Animated Scan Mirror Icon

  7. WISE Survey Strategy Provides Minimum of 8 Exposures Per Position 1 Orbit 2 Consecutive Orbits 2 Orbits 20 Days Apart • Single observing mode • Minimum 8, median 14 exposures/position after losses to Moon and SAA • Scan mirror enables efficient surveying • 8.8-s exposure/11-s duty cycle • 10% frame to frame overlap • 90% orbit to orbit overlap • Sky covered in 6 months observing

  8. JGC 4/30/2009 Focusing WISE at SDL Fused silica window Mylar sheet (ND filter) Fold mirror WISE Instrument (LHe cooled) Blue Tube (LN2 cooled) Blackbody Pinhole Collimator

  9. Final assembly & test at Ball

  10. WISE is tiny (in the PPF)!

  11. WISE is tiny in the fairing

  12. Launch! 14 Dec 2009 @ 06:09 PST • g

  13. On to Survey Mode • 33 seconds in the life of WISE, 3 of >7000 frames/day

  14. Asteroids Observed by WISE • Four frames of data taken on 2010 Jan. 8 during in-orbit checkout. • Blue = 3.6um; green = 4.6um; red = 12um • Circled asteroids are (L to R in the first frame, diameters in km):17818 MBA  D~12.4153204 MBA   D~2.822006 MBA   D~11.587355 MBA   D~4.380590 MBA   D~4.1 Field of view = 34 x 25 arcmin (whole WISE FOV is 47 x 47 arcmin)

  15. Thus WISE has • Discovered many new Aten class and potentially hazardous asteroids, has determined give radiometric diameters for more than 150,000 objects. • Nearly 4 million asteroid observations, the most of any observatory in 2010 up to 13 Sep 2010.

  16. WISE and Brown Dwarfs • Brown Dwarfs are stars with too little mass to fuse Hydrogen into Helium. • WISE two short wavelength filters are tuned to methane dominated brown dwarf spectra. • WISE could identify brown dwarfs as cool as 200 Kelvin (-100 Fahrenheit) out to 4 light years, the distance to the nearest known star.

  17. Inhabitants of WISE Color Space • SDSS Classifications: • Galaxies • z ~ 0.4 LIRGs • Local LIRGs • Local ULIRGs • QSOs

  18. First Spectroscopically Confirmed WISE Brown Dwarf • WISE 0458+64 spectrum from LUCIFER on LBT. • At the time, was as cool or cooler than any known BD • Mainzer et al 2010 (ApJ in press). W0458+64 W2 = 13.02 W1-W2 = 3.38 J-W2 = 4.45

  19. But wait there’s more • Burgasser et al (in press): 5 WISE BDs • Kirkpatrick et al (submitted) has ≈102 BDs • Triples the number of known T8s • 10× the number of known T9s

  20. H-W2 vs. W1-W2

  21. Who’s the Coolest Dwarf of all? • Is it 1405+55? • J = 20.2 • J-H = -1.5 • W2 = 14.1 • W1 > 18 • J-W2=6.1

  22. Need HST WF3 IR Grism for spectrum • Clearly see the 1.27 and 1.59 μm peaks of a CH4 dominated dwarf

  23. Clear Ammonia Signature • NH3 is cutting the short end of the 1.59 μm bump and narrowing the 1.27 μm bump • A Y dwarf! • Cushing etal submitted

  24. Astrometry so far • 2 WISE positions • 1 Spitzer position • 1 HST position • Proper motion 2.14 ± 0.26 arc-sec/yr • Parallax 0.11 ± 0.08 arc-sec WISE data alone give a 6σ detection of motion. To do this all-sky will require coadding and cataloguing the 2 band data.

  25. H-W2 vs. W1-W2

  26. 1828+2650 • The reddest source of all as seen by the HST • W2 = 14.25, W1-W2>4, H-W2=8.5, J-H≈0.72±0.42

  27. The far-off Universe L* at z=0.33, z=6.4 QSO, z=3 ULIRG: FSC15307 x 3

  28. WISE Band 1 and 2 Dropouts • W1 > 17.4 and W2 > 15.9 and (W3 < 10.6 or W4 < 7.7) • W1814+34 (Eisenhardt et al 2011, Bridge et al 2011) • z=2.452 • Extended Lyman alpha emission (~40 kpc)

  29. SED of W1814+34 • AGN with AV = 50 • Starburst • Spiral Galaxy • Warm Spitzer data to get 3.6 & 4.5 μm since WISE did not detect it at 3.4 & 4.6 μm. • SHARC II (CSO) at 350 μm • VLA radio data • Peak νLν = 1013.38 L

  30. Warm Spitzer Followup • Objects not detected by WISE at 3.4 & 4.6 μm can be measured using warm Spitzer • bigger mirror • longer integration times • Synergy between surveys and great observatories

  31. Many W12 drops • About 1000/sky • High percentage with high z’s: see histogram • Spitzer followup usually picks up 3.6 and 4.5 μm flux • Herschel followup usually detects far-IR flux

  32. AGN Selection • Stern et al poster 333.15 at the Jan 2011 AAS meeting • Density 70/sq.deg • 60% have published z’s in COSMOS field

  33. Z-distribution of WISE AGNs

  34. W1 on z=1.132 SPT-CL 2106-58

  35. Telescope Temperatures

  36. 4 Band Coverage to 5 Aug 2010

  37. End of Cryo Coverage

  38. Final 2 band coverage Ten trillion pixels observed!

  39. Thus WISE has • Discovered many new NEOs and potentially hazardous asteroids and gave radiometric diameters for nearly 200,000 objects. • Searched for the ½ to ⅔ of the stars in the solar neighborhood that have not yet been seen, including the closest stars to the Sun. • Surveyed star formation in the Milky Way and in massive Ultra-Luminous Infrared Galaxies. • Or at least we have the data now: 10 trillion pixels worth. We have lots of work left analyzing this treasure trove of information.

  40. WISE Summary • Launched 14 Dec 2009 • Band centers 3.4, 4.6, 12 & 22 microns • Sensitivity should be better than 0.08, 0.11, 1 & 6 mJy • Saturation at 0.3, 0.5, 0.7 & 10 Jy point sources • Angular Resolution 6, 6, 6 & 12 arc-seconds • Position accuracy about 0.15 arc-seconds 1σ 1-axis for high SNR • Completed all-sky survey 17 July, big tank ran out hydrogen 5 Aug, little tank empty on 29 Sep, two-band survey for asteroids continued until 1 Feb 2011. • Data release plans: • Preliminary release of 57% of the sky on 14 April 2011 • Final release 17 months after survey ended • Data products include image atlas and source catalog http://wise.astro.ucla.edu

  41. Preliminary Data Release • Available at irsa.ipac.caltech.edu

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