Gemini & Subaru Exchange Time: Developing Collaborations

1. Gemini & Subaru Exchange Time: Developing Collaborations Chris Packham University of Florida Chair of the US Gemini Science Advisory Committee Member of the International Gemini Science Committee 15th January, 2009Subaru Users’ Meeting

2. Presentation Goals • Discussion of the attractions of a Subaru-Gemini partnership • Good and bad points to partnership (from Subaru point of view) • Positives • Access to Gemini’s instruments & IR optimization • Access to southern skies • Collaborative with Gemini international community • Negatives • Less time on Subaru for Subaru community (but time on Gemini) • Increased complexities due to more partners involvement • Need to investigate the role of instrumentation development • Increase awareness of Gemini’s capabilities • Subaru-Gemini exchange time

3. My Personal Bias • Linking of observatories maximizes scientific return from our limited resources world • Improved science has got to be the result of any change • In both the respect of PI- and ‘system-’ science output • Duplication of capabilities on observatories cannot be the optimal path • Continuation of process underway • ALMA • TMT & GMT • Space-based • ESO • Any change must be “win-win” & equitable for the communities

4. The GeminiObservatory • 7 country partnership • Northern & southernsky coverage • “One observatory, two telescopes” • Good image quality • IR optimized • Minimal support structure • Silver coating • Instruments Cass mounted • Heavily queue operated • ‘Classical’ available

5. Gemini 2009 l

6. Gemini 2012 l

7. Gemini 2012 l

8. ALTAIR+LGS • Laser system using 10-12 W laser • Equivalent magnitude V~9-10 • Tip/tilt guide stars • Tip/tilt guide stars to R~18 mag • Patrol field ~1 arcmin diameter • Now feeds • NIFS & NIRI imaging & spectroscopy • Expect to feed GNIRS later in 2009 • Started LGS science in 2007A • 1st direct detection of planetary family • Discovered by ALTAIR+NIRI • Follow-up confirmation by Keck AO

9. NIFS: Near-IR Integral Field Spectrometer • Integral Field Unit • Image slicer w/ 29 slices • 3”x3” field • ~70 detector pixels along each slice • Spaxels ~0.1”x0.04” • Spectroscopy • R ~ 5000 • z ,J ,H, K bands • HAWAII-2RG detector • 2048x2048 pixels • 0.9 – 2.5μm • Coronagraphic mode also available NIFS detection of gas inflow in NGC 4051 with 42km/s velocity slices along the H2 profile

10. GNIRS: Gemini Near-InfraRed Spectrograph (GN) • Long Slit • 0.9 – 2.5μm, R~5,900,18,000 • 1.1 – 2.5μm, R~1,700 • 2.9 – 5.5μm, R~1,700, 5,900, 18,000 • ∆λ: R1700: 0.3*λ; R5900: 0.09*λ; R18000: 0.03* λ • Cross-Dispersed • 0.9 – 2.5μm, R=1,700 full coverage • R=5,900, partial coverage • ALADDIN III detector • 1024x1024 pixels • 0.9 – 5.5μm • Seeing-limited and Altair NGS/LGS AO (soon) GNIRS spectra of Z~6 QSOs

11. MIR Capabilities: Michelle & T-ReCS • Imaging • Filters: N, Q + NB • FOV: 28.8”x21.6”; 0.09”/pixel • 320x240 Raytheon array • 5-26μm • FWHM ~0.3” at 10μm • Diffraction limited • Polarimetry available on Michelle • Spectroscopy • T-ReCS • R~100, 1,000 at 10μm • Slits: 0.21”-1.32” x 21.6” • Michelle • R ~100 – 3,000 long slit • R ~10,000 – 30,000 echelle • Slits 0.36”-1.3” wide x 43.2” HST/NICMOS, T-ReCS & Spitzer images of LIRGS

12. Flamingos-2: Near IR Imager and MOS (GS) • General • HAWAII2 detector: 0.95 – 2.5μm • Commissioning mid-2009 • Seeing limited and MCAO ready • Imaging • 6.1’ ∅ FOV; 0.18”/pixel • ~2’ ∅ FOV; 0.09”/pixel MCAO • Y-K filters + NB + F2T2 • Spectroscopy • R ~ 1,200 – 3,000 • FOV: 2'x6' • Long-slit or custom multi-slit masks (9 held at once) • 50-80 slits per mask? Flamingos-2 Slit/Mask Wheel

13. Multi-instrument queue observing “Queue” is versatile • Optimized execution of programs for conditions • High completion rate of high priority programs • High shutter open efficiency: rapid switch of programs and/or instruments • Fast response programs enabled Gemini South GMOS-N Gemini North Michelle GMOS-S GNIRS NIRI Altair T-ReCS

14. Future Instruments • MCAO • Multi-Conjugate Adaptive Optics • Nearly complete, 1st light 2009 • GPI • Gemini Planet Imager • Under construction, 1st light 2011, ‘Aspen’ instrument • GLAO • Ground Layer Adaptive Optics • Proposed – ‘Aspen’ instrument • WFMOS • Wide Field Multi-Object Spectrograph • Proposed, top rated ‘Aspen’ instrument Aspen was the community (bottom-up), science driven, definition of the next generation of Gemini instruments

15. AO at Gemini • Altair (GN) • LGS/NGS modes • 177 element DM • 10W, 589nm laser • Strehls of 20-40% NGS; 10-20% LGS in H-K • MCAO (GS) • Mutli-conjugate AO • Strehls ~45-80% over 1-2' FOV at 1-2.5μm • GSAOI imager: 1.4’x1.4’ FOV; 0.02”/pixel; 4 H2RG detectors. • Commissioning expected 2009 • GLAO (GN) (possible future capability) • Ground Layer AO • Expected to deliver IQ20 80% of the time

16. Multi-Conjugate AO • MCAO corrects multiple layers of turbulence and overcomes the cone-effect • Traditional AO systems produce image quality that degrades off-axis; MCAO’s image quality is much more uniform, even over several square arcmin • VLT technology demonstration system (MAD) showed that MCAO works using natural guide stars • 1st light late 2009 H-band (1.6µm) Image Quality Traditional AO MCAO  More sensitive  Wider fields  New science

17. Electronics Existing tip-tilt and translation stages Adaptive Secondary Mirror GLAO (Possible Future Capability) • A GLAO system on MK should produce 20-percentile seeing 80% of the time • The GLAO conceptual design • “Backwards compatible” with current instrument support structure and instruments • Includes adaptive secondary mirror • Uses modified MCAO laser projection system • Includes a new acquisition and guidance system that incorporates all the necessary wavefront sensors • Works with the existing Altair system

18. GPI Overview • GPI uses combination of optical systems to permit high contrast imaging <0.2” from bright stars • High-Order Adaptive Optics System • Combination “Woofer/Tweeter” AO system that has >10x actuators than ALTAIR and will yield Strehls of 80-90% • Interferometer • Measure and compensate for “super speckles” • Advanced coronagraph • Rejects light from the bright central star • Integral Field Spectrometer • Multi-wavelength image of planets in the field • 1st light 2011

19. Large Scale View 1/2 • Many Gemini & Subaru instruments have similar science goals & tech. drivers • Should be careful to avoid duplicating too many capabilities • Repetition of future instruments unlikely to provide efficient next scientific steps • Specialization of telescopes offers perhaps the best science return on investment • Sharing observatory resources maintains broad range of instruments & science

20. Large Scale View 2/2 • Pooling of resources for future can strengthen both communities • 30m class telescopes will be necessarily international • Use of shared time between telescopes very exciting • Gemini-Subaru and Gemini-Keck exchange time well used & loved • Currently Subaru-Gemini time is rather limited (5 nights per semester) • Could discourage potential applicants? • Help available for applications

21. Mapping H2 Emission of T Tauri Stars Beck, McGreger, Takami & Tae-Soo, ApJ 2007 • NIFS detection of H2 emission over 200 AU • All have H2 excitation temp ~2-3 times higher than predicted from UV or X-ray heating models • H2 line ratios most consistent with shock excitation • Emission likely associated with HH outflows • Rather than quiescent disk H2 gas stimulated by central star Extended v = 1-0 S(1) H2 emission around 6 T Tauri stars

22. NIFS Dissects HL Tau’s JetTakami, Beck , Tae-Soo et al. 2007, ApJL • ALTAIR/NIFS focus on HL Tau jet “central engine” • <0.2” spatial resolution • [Fe II] highly collimated • Compared to more extended H2 (similar to CO outflow pattern) • H2 outflow over a scale of only 150 pc • Arc-like bipolar features predicted to change over a few years • Monitoring will provide dynamical age • Consistent with jet surrounded by unseen wide-angled wind • Wind interaction with ambient gas produces bipolar cavity and shocked H2 emission [FeII] in contours, H2 at 2.122 m in blue H2 in blue, Continuum at 2.12 m as countours NIFS field 3 x 3 arcsec2 0.1 arcsec slitlets

23. Massive Evolved Galaxy at z=1.26Matsuoka et al. 2008, ApJ • GMOS-S & GNIRS observations of TSPS J1239-0957 at z = 1.26 • Wide spectrum optical & IR coverage of southern object • Typically other work uses optical spectra and NIR broad-band photometry • Bright ERO formed when universe was 2-3 Gyr, then passively evolved • M* = 1011.5 Msun • Direct ancestor of brightest E and spheroidals of today • Presence of such a massive galaxy could favor hierarchical formation scenarios

24. Conclusions • Collaborations between Subaru & Gemini potentially very attractive and complimentary for both communities • Subaru’s world leading optical observations - SC, HSC & WFMOS • Drive for IR image quality, NIR & MIR at Gemini • ‘Guiding light’ must be ‘win-win’ & equitable for partners • Need to consider carefully instrument development options • Collaborative instrument development teams? • Upcoming Gemini next generation instrument workshop • Timing seems appropriate as • Three mature telescopes • Instruments growing in complexity & expense • Move to internationally based science (i.e. TMT) • Early science results promising, but much more potential