Your search keyword '"K. E. Saavik Ford"' showing total 2 results

1. NIRISS aperture masking interferometry: an overview of science opportunities

Author

Alexandra Z. Greenbaum, Barry McKernan, Andre Martel, Étienne Artigau, K. E. Saavik Ford, Kevin Volk, Paul Goudfrooij, Anand Sivaramakrishnan, David Lafrenière, Loic Albert, Alex W. Fullerton, and René Doyon

Subjects

Physics, James Webb Space Telescope, Astrophysics::Instrumentation and Methods for Astrophysics, FOS: Physical sciences, Astronomy, Astrophysics::Cosmology and Extragalactic Astrophysics, Exoplanet, Interferometry, Planet, Aperture masking interferometry, Astrophysics::Solar and Stellar Astrophysics, Angular resolution, Astrophysics::Earth and Planetary Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics, Adaptive optics, Instrumentation and Methods for Astrophysics (astro-ph.IM), Spectrograph, Astrophysics::Galaxy Astrophysics

Abstract

JWST's Near-Infrared Imager and Slitless Spectrograph (NIRISS) includes an Aperture Masking Interferometry (AMI) mode designed to be used between 2.7{\mu}m and 4.8{\mu}m. At these wavelengths, it will have the highest angular resolution of any mode on JWST, and, for faint targets, of any existing or planned infrastructure. NIRISS AMI is uniquely suited to detect thermal emission of young massive planets and will permit the characterization of the mid-IR flux of exoplanets discovered by the GPI and SPHERE adaptive optics surveys. It will also directly detect massive planets found by GAIA through astrometric accelerations, providing the first opportunity ever to get both a mass and a flux measurement for non-transiting giant planets. NIRISS AMI will also enable the study of the nuclear environment of AGNs., Comment: Presented at SPIE Astronomical Telescopes + Instrumentation 2014

Published

2014

2. Non-redundant Aperture Masking Interferometry (AMI) and segment phasing with JWST-NIRISS

Author

David Lafrenière, K. E. Saavik Ford, Andre Martel, Barry McKernan, Anthony Cheetham, Anand Sivaramakrishnan, Alexandra Z. Greenbaum, René Doyon, Anton M. Koekemoer, James P. Lloyd, Frantz Martinache, Michael J. Ireland, Mathilde Beaulieu, Peter G. Tuthill, and Peter Teuben

Subjects

Physics, Wavefront, business.industry, James Webb Space Telescope, law.invention, Telescope, Interferometry, Optics, law, Aperture masking interferometry, Deconvolution, Adaptive optics, business, Coronagraph, Remote sensing

Abstract

The Aperture Masked Interferometry (AMI) mode on JWST-NIRISS is implemented as a 7-hole, 15% throughput, non-redundant mask (NRM) that operates with 5-8% bandwidth filters at 3.8, 4.3, and 4.8 microns. We present refined estimates of AMI's expected point-source contrast, using realizations of noise matched to JWST pointing requirements, NIRISS detector noise, and Rev-V JWST wavefront error models for the telescope and instrument. We describe our point-source binary data reduction algorithm, which we use as a standardized method to compare different observational strategies. For a 7.5 magnitude star we report a 10-a detection at between 8.7 and 9.2 magnitudes of contrast between 100 mas to 400 mas respectively, using closure phases and squared visibilities in the absence of bad pixels, but with various other noise sources. With 3% of the pixels unusable, the expected contrast drops by about 0.5 magnitudes. AMI should be able to reach targets as bright as M=5. There will be significant overlap between Gemini-GPI and ESO-SPHERE targets and AMI's search space, and a complementarity with NIRCam's coronagraph. We also illustrate synthesis imaging with AMI, demonstrating an imaging dynamic range of 25 at 100 mas scales. We tailor existing radio interferometric methods to retrieve a faint bar across a bright nucleus, and explain the similarities to synthesis imaging at radio wavelengths. Modest contrast observations of dusty accretion flows around AGNs will be feasible for NIRISS AMI. We show our early results of image-plane deconvolution as well. Finally, we report progress on an NRM-inspired approach to mitigate mission-level risk associated with JWST's specialized wavefront sensing hardware. By combining narrow band and medium band Nyquist-sampled images taken with a science camera we can sense JWST primary mirror segment tip-tilt to lOmas, and piston to a few nm. We can sense inter-segment piston errors of up to 5 coherence lengths of the broadest bandpass filter used ( 250-500 0m depending on the filters). Our approach scales well with an increasing number of segments, which makes it relevant for future segmented-primary space missions.

Published

2012