Attaining m s−1 level intrinsic Doppler precision with RHEA, a low-cost single-mode spectrograph

Tobias Feger; Michael J. Ireland; Christian Schwab; Joao Bento; Carlos Bacigalupo; David W. Coutts

doi:10.1007/s10686-016-9510-5

Attaining m s⁻¹ level intrinsic Doppler precision with RHEA, a low-cost single-mode spectrograph

Tobias Feger^*, Michael J. Ireland, Christian Schwab, Joao Bento, Carlos Bacigalupo, David W. Coutts

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

14 Citations (Scopus)

Abstract

We present RHEA, a compact and inexpensive single-mode spectrograph which is built to exploit the capabilities of modest-sized telescopes in an economic way. The instrument is fed by up to seven optical waveguides with the aim of achieving an efficient and modal-noise-free unit, suitable for attaining extreme Doppler precision. The cross-dispersed layout features a wavelength coverage from 430–650 nm, with spectral resolution of R ∼75,000. When coupled to small telescopes using fast tip/tilt control, our instrument is well-suited to sensitive spectroscopy. Example science cases are accurate radial velocity studies of low to intermediate-mass giant stars with the purpose of searching for giant plants and using asteroseismology to simultaneously measure the host star parameters. In this paper we describe the final instrument design and present first results from testing the internal stability.

Original language	English
Pages (from-to)	285-300
Number of pages	16
Journal	Experimental Astronomy
Volume	42
Issue number	3
DOIs	https://doi.org/10.1007/s10686-016-9510-5
Publication status	Published - 1 Dec 2016

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title = "Attaining m s−1 level intrinsic Doppler precision with RHEA, a low-cost single-mode spectrograph",

abstract = "We present RHEA, a compact and inexpensive single-mode spectrograph which is built to exploit the capabilities of modest-sized telescopes in an economic way. The instrument is fed by up to seven optical waveguides with the aim of achieving an efficient and modal-noise-free unit, suitable for attaining extreme Doppler precision. The cross-dispersed layout features a wavelength coverage from 430–650 nm, with spectral resolution of R ∼75,000. When coupled to small telescopes using fast tip/tilt control, our instrument is well-suited to sensitive spectroscopy. Example science cases are accurate radial velocity studies of low to intermediate-mass giant stars with the purpose of searching for giant plants and using asteroseismology to simultaneously measure the host star parameters. In this paper we describe the final instrument design and present first results from testing the internal stability.",

keywords = "Asteroseismology, Extrasolar planets, High-resolution, Instrumentation, Radial velocity, Single-mode spectrograph, Tube lens",

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AU - Feger, Tobias

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AU - Schwab, Christian

AU - Bento, Joao

AU - Bacigalupo, Carlos

AU - Coutts, David W.

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KW - Extrasolar planets

KW - High-resolution

KW - Instrumentation

KW - Radial velocity

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Attaining m s⁻¹ level intrinsic Doppler precision with RHEA, a low-cost single-mode spectrograph

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