Separating planetary reflex Doppler shifts from stellar variability in the wavelength domain

A Collier Cameron; E B Ford; S Shahaf; S Aigrain; X Dumusque; R D Haywood; A Mortier; D F Phillips; L Buchhave; M Cecconi; H Cegla; R Cosentino; M Crétignier; A Ghedina; M González; D W Latham; M Lodi; M López-Morales; G Micela; E Molinari; F Pepe; G Piotto; E Poretti; D Queloz; J San Juan; D Ségransan; A Sozzetti; A Szentgyorgyi; S Thompson; S Udry; C Watson

doi:10.1093/mnras/stab1323

Separating planetary reflex Doppler shifts from stellar variability in the wavelength domain

A Collier Cameron^*, E B Ford, S Shahaf, S Aigrain, X Dumusque, R D Haywood, A Mortier, D F Phillips, L Buchhave, M Cecconi, H Cegla, R Cosentino, M Crétignier, A Ghedina, M González, D W Latham, M Lodi, M López-Morales, G Micela, E MolinariF Pepe, G Piotto, E Poretti, D Queloz, J San Juan, D Ségransan, A Sozzetti, A Szentgyorgyi, S Thompson, S Udry, C Watson

^*Corresponding author for this work

Physics and Astronomy

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Abstract

Stellar magnetic activity produces time-varying distortions in the photospheric line profiles of solar-type stars. These lead to systematic errors in high-precision radial-velocity measurements, which limit efforts to discover and measure the masses of low-mass exoplanets with orbital periods of more than a few tens of days. We present a new data-driven method for separating Doppler shifts of dynamical origin from apparent velocity variations arising from variability-induced changes in the stellar spectrum. We show that the autocorrelation function (ACF) of the cross-correlation function used to measure radial velocities is effectively invariant to translation. By projecting the radial velocities on to a subspace labelled by the observation identifiers and spanned by the amplitude coefficients of the ACF’s principal components, we can isolate and subtract velocity perturbations caused by stellar magnetic activity. We test the method on a 5-yr time sequence of 853 daily 15-min observations of the solar spectrum from the HARPS-N instrument and solar-telescope feed on the 3.58-m Telescopio Nazionale Galileo. After removal of the activity signals, the heliocentric solar velocity residuals are found to be Gaussian and nearly uncorrelated. We inject synthetic low-mass planet signals with amplitude K = 40 cm s⁻¹ into the solar observations at a wide range of orbital periods. Projection into the orthogonal complement of the ACF subspace isolates these signals effectively from solar activity signals. Their semi-amplitudes are recovered with a precision of ∼ 6.6 cm s⁻¹, opening the door to Doppler detection and characterization of terrestrial-mass planets around well-observed, bright main-sequence stars across a wide range of orbital periods.

Original language	English
Pages (from-to)	1699-1717
Number of pages	19
Journal	Monthly Notices of the Royal Astronomical Society
Volume	505
Issue number	2
Early online date	12 May 2021
DOIs	https://doi.org/10.1093/mnras/stab1323
Publication status	Published - Aug 2021

Keywords

methods: statistical
techniques: radial velocities
techniques: spectroscopic
Sun: photosphere
planets and satellites: general

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CameronC2021SeparatingFinal published version, 5.72 MBLicence: Creative Commons: Attribution (CC BY)

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Collier Cameron, A., Ford, E. B., Shahaf, S., Aigrain, S., Dumusque, X., Haywood, R. D., Mortier, A., Phillips, D. F., Buchhave, L., Cecconi, M., Cegla, H., Cosentino, R., Crétignier, M., Ghedina, A., González, M., Latham, D. W., Lodi, M., López-Morales, M., Micela, G., ... Watson, C. (2021). Separating planetary reflex Doppler shifts from stellar variability in the wavelength domain. Monthly Notices of the Royal Astronomical Society, 505(2), 1699-1717. https://doi.org/10.1093/mnras/stab1323

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title = "Separating planetary reflex Doppler shifts from stellar variability in the wavelength domain",

abstract = "Stellar magnetic activity produces time-varying distortions in the photospheric line profiles of solar-type stars. These lead to systematic errors in high-precision radial-velocity measurements, which limit efforts to discover and measure the masses of low-mass exoplanets with orbital periods of more than a few tens of days. We present a new data-driven method for separating Doppler shifts of dynamical origin from apparent velocity variations arising from variability-induced changes in the stellar spectrum. We show that the autocorrelation function (ACF) of the cross-correlation function used to measure radial velocities is effectively invariant to translation. By projecting the radial velocities on to a subspace labelled by the observation identifiers and spanned by the amplitude coefficients of the ACF{\textquoteright}s principal components, we can isolate and subtract velocity perturbations caused by stellar magnetic activity. We test the method on a 5-yr time sequence of 853 daily 15-min observations of the solar spectrum from the HARPS-N instrument and solar-telescope feed on the 3.58-m Telescopio Nazionale Galileo. After removal of the activity signals, the heliocentric solar velocity residuals are found to be Gaussian and nearly uncorrelated. We inject synthetic low-mass planet signals with amplitude K = 40 cm s−1 into the solar observations at a wide range of orbital periods. Projection into the orthogonal complement of the ACF subspace isolates these signals effectively from solar activity signals. Their semi-amplitudes are recovered with a precision of ∼ 6.6 cm s−1, opening the door to Doppler detection and characterization of terrestrial-mass planets around well-observed, bright main-sequence stars across a wide range of orbital periods.",

keywords = "methods: statistical, techniques: radial velocities, techniques: spectroscopic, Sun: photosphere, planets and satellites: general",

author = "A Collier Cameron and Ford, {E B} and S Shahaf and S Aigrain and X Dumusque and Haywood, {R D} and A Mortier and Phillips, {D F} and L Buchhave and M Cecconi and H Cegla and R Cosentino and M Cr{\'e}tignier and A Ghedina and M Gonz{\'a}lez and Latham, {D W} and M Lodi and M L{\'o}pez-Morales and G Micela and E Molinari and F Pepe and G Piotto and E Poretti and D Queloz and Juan, {J San} and D S{\'e}gransan and A Sozzetti and A Szentgyorgyi and S Thompson and S Udry and C Watson",

year = "2021",

month = aug,

doi = "10.1093/mnras/stab1323",

language = "English",

volume = "505",

pages = "1699--1717",

journal = "Monthly Notices of the Royal Astronomical Society",

issn = "0035-8711",

publisher = "SIPRI/Oxford University Press",

number = "2",

}

Collier Cameron, A, Ford, EB, Shahaf, S, Aigrain, S, Dumusque, X, Haywood, RD, Mortier, A, Phillips, DF, Buchhave, L, Cecconi, M, Cegla, H, Cosentino, R, Crétignier, M, Ghedina, A, González, M, Latham, DW, Lodi, M, López-Morales, M, Micela, G, Molinari, E, Pepe, F, Piotto, G, Poretti, E, Queloz, D, Juan, JS, Ségransan, D, Sozzetti, A, Szentgyorgyi, A, Thompson, S, Udry, S & Watson, C 2021, 'Separating planetary reflex Doppler shifts from stellar variability in the wavelength domain', Monthly Notices of the Royal Astronomical Society, vol. 505, no. 2, pp. 1699-1717. https://doi.org/10.1093/mnras/stab1323

TY - JOUR

T1 - Separating planetary reflex Doppler shifts from stellar variability in the wavelength domain

AU - Collier Cameron, A

AU - Ford, E B

AU - Shahaf, S

AU - Aigrain, S

AU - Dumusque, X

AU - Haywood, R D

AU - Mortier, A

AU - Phillips, D F

AU - Buchhave, L

AU - Cecconi, M

AU - Cegla, H

AU - Cosentino, R

AU - Crétignier, M

AU - Ghedina, A

AU - González, M

AU - Latham, D W

AU - Lodi, M

AU - López-Morales, M

AU - Micela, G

AU - Molinari, E

AU - Pepe, F

AU - Piotto, G

AU - Poretti, E

AU - Queloz, D

AU - Juan, J San

AU - Ségransan, D

AU - Sozzetti, A

AU - Szentgyorgyi, A

AU - Thompson, S

AU - Udry, S

AU - Watson, C

PY - 2021/8

Y1 - 2021/8

N2 - Stellar magnetic activity produces time-varying distortions in the photospheric line profiles of solar-type stars. These lead to systematic errors in high-precision radial-velocity measurements, which limit efforts to discover and measure the masses of low-mass exoplanets with orbital periods of more than a few tens of days. We present a new data-driven method for separating Doppler shifts of dynamical origin from apparent velocity variations arising from variability-induced changes in the stellar spectrum. We show that the autocorrelation function (ACF) of the cross-correlation function used to measure radial velocities is effectively invariant to translation. By projecting the radial velocities on to a subspace labelled by the observation identifiers and spanned by the amplitude coefficients of the ACF’s principal components, we can isolate and subtract velocity perturbations caused by stellar magnetic activity. We test the method on a 5-yr time sequence of 853 daily 15-min observations of the solar spectrum from the HARPS-N instrument and solar-telescope feed on the 3.58-m Telescopio Nazionale Galileo. After removal of the activity signals, the heliocentric solar velocity residuals are found to be Gaussian and nearly uncorrelated. We inject synthetic low-mass planet signals with amplitude K = 40 cm s−1 into the solar observations at a wide range of orbital periods. Projection into the orthogonal complement of the ACF subspace isolates these signals effectively from solar activity signals. Their semi-amplitudes are recovered with a precision of ∼ 6.6 cm s−1, opening the door to Doppler detection and characterization of terrestrial-mass planets around well-observed, bright main-sequence stars across a wide range of orbital periods.

AB - Stellar magnetic activity produces time-varying distortions in the photospheric line profiles of solar-type stars. These lead to systematic errors in high-precision radial-velocity measurements, which limit efforts to discover and measure the masses of low-mass exoplanets with orbital periods of more than a few tens of days. We present a new data-driven method for separating Doppler shifts of dynamical origin from apparent velocity variations arising from variability-induced changes in the stellar spectrum. We show that the autocorrelation function (ACF) of the cross-correlation function used to measure radial velocities is effectively invariant to translation. By projecting the radial velocities on to a subspace labelled by the observation identifiers and spanned by the amplitude coefficients of the ACF’s principal components, we can isolate and subtract velocity perturbations caused by stellar magnetic activity. We test the method on a 5-yr time sequence of 853 daily 15-min observations of the solar spectrum from the HARPS-N instrument and solar-telescope feed on the 3.58-m Telescopio Nazionale Galileo. After removal of the activity signals, the heliocentric solar velocity residuals are found to be Gaussian and nearly uncorrelated. We inject synthetic low-mass planet signals with amplitude K = 40 cm s−1 into the solar observations at a wide range of orbital periods. Projection into the orthogonal complement of the ACF subspace isolates these signals effectively from solar activity signals. Their semi-amplitudes are recovered with a precision of ∼ 6.6 cm s−1, opening the door to Doppler detection and characterization of terrestrial-mass planets around well-observed, bright main-sequence stars across a wide range of orbital periods.

KW - methods: statistical

KW - techniques: radial velocities

KW - techniques: spectroscopic

KW - Sun: photosphere

KW - planets and satellites: general

U2 - 10.1093/mnras/stab1323

DO - 10.1093/mnras/stab1323

M3 - Article

SN - 0035-8711

VL - 505

SP - 1699

EP - 1717

JO - Monthly Notices of the Royal Astronomical Society

JF - Monthly Notices of the Royal Astronomical Society

IS - 2

ER -

Separating planetary reflex Doppler shifts from stellar variability in the wavelength domain

Abstract

Keywords

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