Abstract
The Daniel K. Inouye Solar Telescope (DKIST) is designed to deliver accurate spectropolarimetric calibrations across a wide wavelength range and large field of view for solar disk, limb, and coronal observations. DKIST instruments deliver spectral resolving powers of up to 300,000 in multiple cameras of multiple instruments sampling nanometer scale bandpasses. We require detailed knowledge of optical coatings on all optics to ensure that we can predict and calibrate the polarization behavior of the system. Optical coatings can be metals protected by many dielectric layers or several-micron-thick dichroics. Strong spectral gradients up to 60 deg retardance per nanometer wavelength and several percent diattenuation per nanometer wavelength are observed in such coatings. Often, optical coatings are not specified with spectral gradient targets for polarimetry in combination with both average- and spectral threshold-type specifications. DKIST has a suite of interchangeable dichroic beam splitters using up to 96 layers. We apply the Berreman formalism in open-source Python scripts to derive coating polarization behavior. We present high spectral resolution examples on dichroics where transmission can drop 10% with associated polarization changes over a 1-nm spectral bandpass in both mirrors and dichroics. We worked with a vendor to design dichroic coatings with relatively benign polarization properties that pass spectral gradient requirements and polarization requirements in addition to reflectivity. We now have the ability to fit multilayer coating designs which allow us to predict system-level polarization properties of mirrors, antireflection coatings, and dichroics at arbitrary incidence angles, high spectral resolving power, and on curved surfaces through optical modeling software packages. Performance predictions for polarization at large astronomical telescopes require significant metrology efforts on individual optical components combined with system-level modeling efforts. We show our custom-built laboratory spectropolarimeter and metrology efforts on protected metal mirrors, antireflection coatings, and dichroic mirror samples.
Highlights
We have shown how the Mueller matrices of the coudé relay optics, the adaptive optics (AO) system, the facility instrument distribution optics (FIDO) dichroics, and internal instrument optics are combined into a single Mueller matrix representing all optics ahead of the polarization modulator
We have shown an example of the DL-NIRSP instrument in the focal ratio (F∕)24 configuration and describe the 19 optical surfaces that will impact this system Mueller matrix
We have shown examples of the additional polarization effects from mirror combinations in two Daniel K. Inouye Solar Telescope (DKIST) instruments: visible spectropolarimeter (ViSP) and DL-NIRSP
Summary
In HS17,11 we outlined the DKIST optical layout and properties of a very simple enhanced silver mirror coating model This coating recipe was used in Zemax to estimate the field of view and beam footprint variation of the combined system optics to visible spectropolarimeter (ViSP) and Cryo-NIRSP. We present measurements and coating models for all optics presently coated in the DKIST telescope and most of the first-light instrument suite along with system-level predictions for polarization performance. The Mueller matrix combines polarization behavior of six surfaces through the feed optics and AO system, six surfaces with complex dichroic coatings in FIDO, and another seven mirror surfaces inside DL-NIRSP ahead of the modulator. The transmission is shown in the [0,0] element, while all other elements are normalized by transmission for convenient interpretation
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