Magdalena Ridge Observatory Interferometer M. J. Creech-Eakman
Overview of Talk Instrument/Site Description Science Reference Mission Technical Progress Personnel/Staffing Schedule Conclusions SPIE - Glasgow 2004 2
Magdalena Ridge Observatory Site Altitude 10,500 ft -- outside Socorro, NM US Fed. Funding Completed EIS Construction permit in place Site infrastructure being implemented 2004 Ongoing site testing median r 0 = 8.5 cm @ 500 nm SPIE - Glasgow 2004 3
MRO Interferometer NW SE NE BCF 10 1.4 m alt-alt telescopes Tip-tilt, no higher AO Baselines from 8-4008 meters 34 kinematic pads 0.6-2.4 micron operation Vacuum transport and DL Parallel FT and science combiners Fixed, moderate spectral resolution backends Visitor instrument port SPIE - Glasgow 2004 4
Science Reference Mission (i) YSOs and Planetary Companions: Protostellar accretion: Imaging of thermal dust and scattered emission on sub-au scales. Disk clearing as evidence for the epoch of planet formation. Emission line imaging of jets, outflows, and magnetically channelled accretion. Companions: Frequency of occurrence. Physical and compositional characterisation. Direct detection of sub-stellar stellar companions. Requirements: Tuthill et al., ApJ, 577 (2002). <1mas for disks out to 500 pc 1-10mas 10mas for hot dust Recombination line imaging and spectroscopy R ~ 250 SPIE - Glasgow 2004 5
Science Reference Mission (ii) Stellar Astrophysics: Mass loss in single stars: Convection: latitudinal or longitudinal? Distribution of circumstellar material, the onset of bipolarity, shocks and wind geometries. Mass loss in binaries: Recurrent novae and symbiotics. Orbit, wind and accretion geometry. Eclipsing binaries. Clumpiness in mass transfer. Dynamical studies: Pulsational models for Cepheids, Miras, RV Tauris etc. Tuthill et al, ApJ, 543 (2000) Requirements: 0.3-20mas dust shells, emission nebulae and pulsations <1mas for eclipsing binaries Moderate spectral resolutions for continuum and line imaging SPIE - Glasgow 2004 6 Lane et al, AJ, 573, 330 (2002)
Science Reference Mission (iii) AGN science: Direct detection of the 30-2000 mas obscuring tori. Geometry and orientation of tori. Correlations with other observables. 0.1-0.5 mas 10-100 mas Nature and contribution of nuclear and extranuclear starbursts. Imaging and dynamics of the broad line region. Detection and characterization of optical and IR counterparts of synchrotron jets. SPIE - Glasgow 2004 7 Veron-Cetty & Veron, A&A, 1992 Verification of the unified model: 1 µas
Science Reference Mission (iv) Requirements Telescope size of 1.4 m H magnitude = 14 for group delay tracking limit Spatial scales of 0.3 to 30 mas Baselines from 8 to 400 m High throughput to achieve sensitivity limit Fifteen reflections from primary to detectors Optimized coatings for 0.6-2.4 microns Large number of telescopes Optimized for model-independent imaging SPIE - Glasgow 2004 8
Technical Progress (i) SPIE - Glasgow 2004 9
Technical Progress (ii) Coatings COAST dichroic <0.5% losses over 0.6-2.4 microns Designed coating (Baldwin et al. 2004) <0.1% losses over optical; 99% throughput in NIR SPIE - Glasgow 2004 10
Telescopes Technical Progress (iii) 1.4m aperture Alt-alt mount Articulated tertiary Optics table T/T & ADC Feeds into vacuum transport 7 responses to ROM SPIE - Glasgow 2004 11
Technical Progress (iv) Transporter concepts Independent consultant rails too expensive Wheeled dome 6 m shown Boat-lifter Studying g loading requirements and repeatability SPIE - Glasgow 2004 12
Technical Progress (v) Delay lines concept No rails Rotational control Active secondary Inductive power transmission and RF communication Prototype under test at Cavendish Lab SPIE - Glasgow 2004 13
Technical Progress (vi) Beam combiners 15 mm beams Optically contacted devices Limited degrees of freedom Ease of alignment and calibration Long-term stability SPIE - Glasgow 2004 14
Technical Progress (vii) Detectors Optical (T/T & science) E2V back-illuminated CCD87 On-chip gain zero read-noise Pixel rates > 1MHz per beam Available off-the the-shelf Infrared (FT & science) Rockwell Calico AO 1e - at 500 khz pixel rate 8 on-chip amp designs under study at Caltech/ESO SPIE - Glasgow 2004 15
Technical Progress (viii) BCF/DL buildings Initial designs concentrating on: Berm building Room-within within-a-room Design contract to be let Q3 `04 Build contract to be let Q2 `05 SPIE - Glasgow 2004 16
Personnel/Staffing PI V. Romero/Deputy PI D. Westpfahl Proj Manager M. Sirota Proj Architects D. Buscher and C. Haniff Proj Scientist M. Creech-Eakman Lead Optomechanical Eng. J. Kern Lead Control Software Eng. T. Coleman Total Personnel: 15 FTE hiring 8 more positions over next year (mechanical, camera systems, electrical, software, postdocs and technicians) Partner COAST group from Cambridge Spending Oversight - NRL SPIE - Glasgow 2004 17
Phase A: Phased Build 6 telescopes, 225 m baselines, NIR science $40M Final Instrument: 10 telescopes, 400 m baselines, NIR & optical science $70M SPIE - Glasgow 2004 18
Proposed Schedule Let RFP for telescopes - 4 th Q, 04 Design Review 1 st Q, 05 Begin building BCF & piers 3 rd Q, 05 Telescopes arrive 1 st Q, 07 First fringes 4 th Q, 07 First closure phase 2 nd Q, 08 First Nature paper shortly thereafter SPIE - Glasgow 2004 19
Conclusions MROI first facility class interferometer with a design which is optimized for model- independent imaging over a large range of spatial scales. SPIE - Glasgow 2004 20
More information? Jobs postings: Michelle Creech-Eakman, Mark Sirota, Chris Haniff or David Buscher (Camera Systems Engineer, Mechanical Engineer, Electronics Engineer, Postdoc) NMT Physics Dept: expect 3-43 4 faculty retires in next 6 years Posters: 5491:144-147,183, 147,183, 5489:83 Papers: 5491:59, 78, 98 SPIE - Glasgow 2004 21
Backup Slides SPIE - Glasgow 2004 22
SNR Calculation Assumptions: r 0 = 14 cm, T/T 10 Hz, windspeed 10m/s, 1.4m aperture, errors/vibrations λ/10 rms, 1.5e - readnoise, pairwise combination, H band, unresolved source Results: N = 80 photons at H, N background <10 photons, n pixels = 20 = 5 channels X 4 bins SNR Calculation: SNR V 2 N 2 / (N + N background + n pixels σ 2 ) = 0.77 Buscher (1988) showed SNR = 0.33 is all that is required for group delay (fringe envelope) tracking SPIE - Glasgow 2004 23
Why 1.4 m apertures? SNR for H=14 vs Aperture Diameter 1.00 0.90 0.80 0.70 Fringe Tracking SNR 0.60 0.50 0.40 0.30 sigma=1.5e sigma=2.0e sigma=3.0e 0.20 0.10 0.00 1.00 1.20 1.40 1.60 1.80 2.00 2.20 Aperture Diameter /m SPIE - Glasgow 2004 24
Throughput Calculation Telescope primary - Al All other mirrors overcoated Ag Infrasil windows and substrates Custom dichroic & AR coatings Extra 1% losses at each exposed surface Total 0.190 Atmosphere 0.970 Telescope 0.710 Interferometer 0.490 Dewar 0.565 Main optics 0.847 ADC 0.882 TT pickoff 0.951 Relay optics 0.776 Delay lines 0.913 Beam combiner 0.691 Optics 0.869 Detector 0.650 SPIE - Glasgow 2004 25