Coronagraphic Imaging of Exoplanets with NIRCam

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Coronagraphic Imaging of Exoplanets with NIRCam C. Beichman NASA Exoplanet Science Institute, Jet Propulsion Laboratory, California Institute of Technology For the NIRCam Team September 27, 2016 Copyright 2016 California Institute of Technology. Government sponsorship acknowledged.

JWST Telescope Coronagraph Image Masks Coronagraph NIRCam Pickoff Mirror Collimator Optics Concept Camera Optics Telescope Focal Surface Pupil Wheel Filter Wheel Coronagraph Wedge FPA Coronagraph Image Masks NIRCam Optics Field of View Without Coronagraph Wedge FPA Calibration Source With Coronagraph Wedge Not to scale Krist et al 2009 & 2010, SPIE

NIRCam Focal Plane Masks FWHM c = 0.58 (4 /D @ 4.6 m) FWHM c = 0.27 (4 /D @ 2.1 m) FWHM = 0.82 (6 /D @ 4.3 m) Krist et al 2009 & 2010, SPIE FWHM = 0.64 (6 /D @ 3.35 m) 2 wedge shaped masks for known geometries give best inner working angle (IWA)=4 /D~0.13 3 circular (sombrero) masks for 360 o coverage with larger IWA= 6 /D~0.19 FWHM = 0.40 (6 /D @ 2.1 m) 3

NIRCam Coronagraph Lyot Stops Clear regions superposed on JWST pupil Throughput ~19%. Lyot stop for 6 /D spot occulters Lyot stop for 4 /D wedge occulters Krist et al 2009 & 2010, SPIE

Coronagraphic Capabilities: Ground and Space -3-4 MIRI 11 um Keck L band Vector Vortex Log Contrast Ratio -5-6 -7-8 TFI/NRM 4.4 um NIRCam 4.4 um Spot P1640/GPI/SPHERE 1.65um TMT 1.65 um -9 0 1 2 3 4 Beichman et al 2010 PASP Theta arcsec

10 5 contrast sources, 10 roll, iterative roll subtraction RMS wavefront change between rolls indicated 0.25 nm 1nm 5 nm 15 nm F210M spot F430M spot 2 10 14

10 6 contrast sources, 10 roll, iterative roll subtraction RMS wavefront change between rolls indicated 0.25 nm 1nm 5 nm 15 nm F210M spot F430M spot 2 10 14

10 7 contrast sources, 10 roll, iterative roll subtraction RMS wavefront change between rolls indicated 0.25 nm 1nm 5 nm 15 nm F210M spot F430M spot 2 10 14

10 8 contrast sources, 10 roll, iterative roll subtraction RMS wavefront change between rolls indicated 0.25 nm 1nm 5 nm 15 nm F210M spot F430M spot 2 10 14

PSF Simulation Tools http://www.stsci.edu/~mperrin/software/webbpsf.html

Illustrative Coronagraphic Observations Observe ~5 known planetary systems with the NIRCam and MIRI coronagraphs to recover physical and atmospheric properties Mass, Radius, Teff, Luminosity, Clouds, Composition Initial Entropy Search for lower mass planets down to ~0.1 0.3 MJup Select targets in angular separation range 0.4 3, masses<13 M Jup Spiegel and Burrows 2012

Monte Carlo analysis over broad range of masses, ages, shows NIRCam (F210M, F250M, F300M, F335M, F430M) + MIRI (F1065C, F1140C, F1550C) yields masses, radii, entropy, etc to 10% for known planets. Are systems like HR8799 the exception or rule? Use JWST s sensitivity to probe to lower masses outside of ~1 2 in F444W where planets brightest and F322W2 to reject stars & galaxies Coronagraphic Observations 2

M Star Survey Kepler and microlensing suggest many small planets orbiting M stars NIRCam coronagraphy can reach Saturn Uranus masses for <150 Myr planets within 15 pc. Probe 10 15 AU: CO snow line favored for ice giant formation Survey ~15 objects at F322W2 and F444W at 3.5 hr/obj Use entire sample to create reference star library

Disk Imaging JWST wavefront error (132 nm) precludes more sensitive searches for debris disks compared with HST Ultimate performance depends on stability between target and reference stars (5 10 nm?)

Use APT 24.3 to Define Program & Estimate Overheads (!) NIRCam: 5 medium + 2 wide filters, 2 rolls, one ref star MIRI: 3 4QPM filters, One ref. star

Pipeline Image Chart from Remi Soummer Processing Built on HST Experience JWST will accumulate PSF references for LOCI, KLIP, PCA, etc. Individual ref stars may be non proprietary Generate pipeline subtracted images as high level product 17

Conclusions NIRCam coronagraphic capabilities are limited by telescope wavefront error large by standards of Extreme AO or future observatories NIRCam s coronagraphic power comes from JWST s WF stability (10 nm?) and low background at >2.4 m and q>1 Acquisition overheads are significant but APT and ETC tools will help with observation planning STScI will provide PSF library and advanced data processing

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