Studying the impact of optical aberrations on diffraction-limited radial velocity instruments

Abstract. Spectrographs nominally contain a degree of quasistatic optical aberrations resulting from the quality of manufactured component surfaces, imperfect alignment, design residuals, thermal effects, and other other associated phenomena involved in the design and construction process. Aberrations that change over time can mimic the line centroid motion of a Doppler shift, introducing radial velocity (RV) uncertainty that increases time-series variability. Even when instrument drifts are tracked using a precise wavelength calibration source, the barycentric motion of the Earth leads to a wavelength shift of stellar light, which causes a translation of the spectrum across the focal plane array by many pixels. The wavelength shift allows absorption lines to experience different optical propagation paths and aberrations over observing epochs. We use physical optics propagation simulations to study the impact of aberrations on precise Doppler measurements made by diffraction-limited, high-resolution spectrographs. Using the optical model of the iLocater spectrograph, we quantify the uncertainties that cross-correlation techniques introduce in the presence of aberrations and barycentric RV shifts. We find that aberrations that shift the point-spread-function photocenter in the dispersion direction, in particular primary horizontal coma and trefoil, are the most concerning. To maintain aberration-induced RV errors <10  cm  /  s, phase errors for these particular aberrations must be held well below 0.05 waves at the instrument operating wavelength. Our simulations further show that wavelength calibration only partially compensates for instrumental drifts, owing to a behavioral difference between how cross-correlation techniques handle aberrations between starlight versus calibration light. Identifying subtle physical effects that influence RV errors will help to ensure that diffraction-limited planet-finding spectrographs are able to reach their full scientific potential.

[1]  Jean-Louis Lizon,et al.  ESPRESSO: the Echelle spectrograph for rocky exoplanets and stable spectroscopic observations , 2010, Astronomical Telescopes + Instrumentation.

[2]  Debra A. Fischer,et al.  Insights on the Spectral Signatures of Stellar Activity and Planets from PCA , 2017, 1708.00491.

[3]  Joss Bland-Hawthorn,et al.  Compact high-resolution spectrographs for large and extremely large telescopes: using the diffraction limit , 2012, Other Conferences.

[4]  Michel Mayor,et al.  ELODIE: A spectrograph for accurate radial velocity measurements , 1996 .

[5]  J Crass,et al.  Final design and on-sky testing of the iLocater SX acquisition camera: broad-band single-mode fibre coupling , 2020, 2010.13795.

[6]  Steven R. Gibson,et al.  A method for generating a synthetic spectrum within Zemax , 2016, Astronomical Telescopes + Instrumentation.

[7]  Justin R. Crepp Improving planet-finding spectrometers , 2014, Science.

[8]  J. Wyant,et al.  Field Guide to Interferometric Optical Testing , 2006 .

[9]  Justin R. Crepp,et al.  Assessing the suitability of H4RG near-infrared detectors for precise Doppler radial velocity measurements , 2019 .

[10]  Rose K. Gibson,et al.  Extreme Precision Radial Velocity Working Group Final Report , 2021, 2107.14291.

[11]  P. Figueira Deriving High-Precision Radial Velocities , 2017, 1711.08347.

[12]  R. P. Butler,et al.  ATTAINING DOPPLER PRECISION OF 3 M S-1 , 1996 .

[13]  Andreas Quirrenbach,et al.  Radial Velocity Prospects Current and Future: A White Paper Report prepared by the Study Analysis Group 8 for the Exoplanet Program Analysis Group (ExoPAG) , 2015 .

[14]  J. Eastman,et al.  Barycentric Corrections at 1 cm s-1 for Precise Doppler Velocities , 2014, 1409.4774.

[15]  Andreas Seifahrt,et al.  Development and construction of MAROON-X , 2016, Astronomical Telescopes + Instrumentation.

[16]  O. Durney,et al.  SOUL: the Single conjugated adaptive Optics Upgrade for LBT , 2016, Astronomical Telescopes + Instrumentation.

[17]  Dani Guzman,et al.  A preliminary design for the GMT-Consortium Large Earth Finder (G-CLEF) , 2014, Astronomical Telescopes and Instrumentation.

[18]  David King,et al.  A radial velocity error budget for single-mode Doppler spectrographs , 2018, Astronomical Telescopes + Instrumentation.

[19]  Justin R. Crepp,et al.  Instrument Simulator and Data Reduction Pipeline for the iLocater Spectrograph , 2018, Publications of the Astronomical Society of the Pacific.

[20]  Frantz Martinache,et al.  Enhancing Stellar Spectroscopy with Extreme Adaptive Optics and Photonics , 2016, 1609.06388.

[21]  Tilo Steinmetz,et al.  State of the Field: Extreme Precision Radial Velocities , 2016, 1602.07939.

[22]  C. Schwab,et al.  Design of NEID, an extreme precision Doppler spectrograph for WIYN , 2016, Astronomical Telescopes + Instrumentation.

[23]  C. Jurgenson,et al.  EXPRES: a next generation RV spectrograph in the search for earth-like worlds , 2016, Astronomical Telescopes + Instrumentation.