SPIRou collects its first photons from stars beyond the Solar System

Portion of a SPIRou frame recorded for AD Leo.
Each group of three vertical bars corres-
ponds to one spectral order, covering a
small region of the spectral domain. The
two left-most vertical bars of each order
contain the spectrum of AD Leo (in two
polarization states) whereas the right-
most one contains a Fabry-Perot spectrum
ensuring that velocimetric variation of the
star can be monitored with a precision of
1 m/s or better.
The spectral lines (along with telluric lines
from the Earth’s atmosphere) show up as
darker horizontal bands in the image.
These lines form a cosmic barcode encryp-
ting information about AD Leo and its
potential planets, that SPIRou will be able
decipher. (©SPIRou team)
Although still in a phase of technical characterization, SPIRou enjoyed a short period of star gazing on April 24 to 26 through the giant eye of the 3.6m Canada-France-Hawaii Telescope (CFHT), atop the dormant Maunakea volcano on the big island of Hawaii. The goal was to verify that SPIRou behaves as expected when staring at the sky rather than at calibration lamps. Only three nights were available for this first on-sky run, before the mountain was hit by a tropical storm and the summit covered with snow from a clouded-out sky. During these three nights, SPIRou already gathered an impressive collection of about 440 spectra of 24 stars, half of which of the red dwarf type – a stellar population that SPIRou will soon scrutinize within its forthcoming large-scale discovery programme in search for nearby planetary systems that will require hundreds of observing nights at CFHT. One of the red dwarfs that SPIRou observed during this first on-sky exercise is AD Leo, a well studied active star located 16 light-years from us in the constellation of Leo, known for its strong magnetic field and hugely energetic flares. Among many verifications, SPIRou demonstrated its ability at detecting the magnetic field of AD Leo through the circular polarization such fields generate in the line profiles of stellar spectra. SPIRou also observed several stars known as “telluric standards”, whose spectra contain mostly telluric lines from the Earth’s atmosphere, of which the infrared domain of SPIRou (spanning 980-2400nm) is particularly rich. Identifying this telluric spectrum is essential to diagnose which features of the SPIRou spectra are attributable to the observed stars and are thus able to inform us about planets potentially orbiting them. These first SPIRou observations were handled by Claire Moutou, resident astronomer at CFHT, with the assistance of the whole CFHT observing team for telescope operation. Preliminary data reduction and analysis was carried out by JF Donati (IRAP/OMP). Links to the Press Releases: Canada-France-Hawaii Telescope (in english) iREx Montréal: french / english versions Université de Montréal (in french) CNRS (in french)
Artist view of an active red dwarf similar to AD Leo, known for its huge flares (©Casey Reed/NASA)
Circular polarization (red) in the spectral lines of AD Leo (blue) reveals the presence of magnetic fields at the surface of this active red dwarf (©J.-F. Donati – IRAP/OMP)
Small portion of the SPIRou spectrum of the active red dwarf AD Leo as observed (w/ telluric lines, red) and once the telluric spectrum (green) is removed (blue). This illustrates how critical telluric subtraction is to properly identify which lines can tell us some information about the observed star, and the planets potentially orbiting it. Located close to the reddest edge of the SPIRou spectrum, this window, containing a plethora of molecular lines, is key for detecting planets (©J.-F. Donati – IRAP/OMP)