Stockholm university

Gloria CanocchiPhD student

About me

I am a PhD student in the Astronomy Department at Stockholm University, working with Dr. Karin Lind as part of the Stars, Planets & Astrobiology group. My research focuses on stellar spectroscopy, particularly in the context of planet-host FGK-type stars. I specialize in modeling stellar spectra using advanced 3D radiation hydrodynamic model atmospheres and non-LTE radiative transfer techniques to better disentangle the planetary absorption signals from the stellar imprints in high-resolution transmission spectra of Hot Jupiters. As instrumentation continues to advance—such as with the upcoming ANDES spectrograph at the Extremely Large Telescope (ELT)—the development and application of highly accurate stellar models are essential for optimizing the characterization of exoplanet atmospheres.

In addition to my research, I am passionate about teaching and actively participate in public outreach, including initiatives like the FysikShow.

Teaching

  • Fall 2021, 2022 & 2023 - Teaching Assistant for the Classic Physics course (Bachelor's level).
  • Spring 2022 & 2023 - Teaching Assistant for the Solar Lab of the Experimentell Fysik course (Bachelor's level).
  • Spring 2024 & 2025 - Teaching Assistant of Lab 1 (Spectroscopy lab) of Experimentell Fysik course (Bachelor's level).

Research projects

Publications

My Licentiate thesis about "Modeling the solar center-to-limb variation of Na and K in 3D non-LTE"  can be found here!

A selection from Stockholm University publication database

  • Discovering planets with PLATO: Comparison of algorithms for stellar activity filtering

    2023. Gloria Canocchi (et al.). Astronomy and Astrophysics 672

    Article

    Context. To date, stellar activity is one of the main limitations in detecting small exoplanets via the transit photometry technique. Since this activity is enhanced in young stars, traditional filtering algorithms may severely underperform in attempting to detect such exoplanets, with shallow transits often obscured by the photometric modulation of the light curve.

    Aims. This paper aims to compare the relative performances of four algorithms developed by independent research groups specifically for the filtering of activity in the light curves of young active stars, prior to the search for planetary transit signals: Notch and LOCoR (N&L), Young Stars Detrending (YSD), K2 Systematics Correction (K2SC), and VARLET. Our comparison also includes the two best-performing algorithms implemented in the Wōtan package: Tukey’s biweight and Huber spline algorithms.

    Methods. For this purpose, we performed a series of injection-retrieval tests of planetary transits of different types, from Jupiter down to Earth-sized planets, moving both on circular and eccentric orbits. These experiments were carried out over a set of 100 realistically simulated light curves of both quiet and active solar-like stars (i.e., F and G types) that will be observed by the ESA Planetary Transits and Oscillations of stars (PLATO) space telescope, starting 2026.

    Results. From the experiments for transit detections, we found that N&L is the best choice in many cases, since it misses the lowest number of transits. However, this algorithm is shown to underperform when the planetary orbital period closely matches the stellar rotation period, especially in the case of small planets for which the biweight and VARLET algorithms work better. Moreover, for light curves with a large number of data-points, the combined results of two algorithms, YSD and Huber spline, yield the highest recovery percentage. Filtering algorithms allow us to obtain a very precise estimate of the orbital period and the mid-transit time of the detected planets, while the planet-to-star radius is underestimated most of the time, especially in cases of grazing transits or eccentric orbits. A refined filtering that takes into account the presence of the planet is thus compulsory for proper planetary characterization analyses.

    Read more about Discovering planets with PLATO
  • 3D non-LTE modeling of the stellar center-to-limb variation for transmission spectroscopy studies

    2024. Gloria Canocchi (et al.). Astronomy and Astrophysics 683

    Article

    Context. Transmission spectroscopy is one of the most powerful techniques used to characterize transiting exoplanets, since it allows for the abundance of the atomic and molecular species in the planetary atmosphere to be measured. However, stellar lines may bias the determination of such abundances if their center-to-limb variations (CLVs) are not properly accounted for.

    Aims. This paper aims to show that three-dimensional (3D) radiation hydrodynamic models and the assumption of non-local ther-modynamic equilibrium (non-LTE) line formation are required for an accurate modeling of the stellar CLV of the Na I D1 and K I resonance lines on transmission spectra.

    Methods. We modeled the CLV of the Na I D1 and K I resonance lines in the Sun with 3D non-LTE radiative transfer. The synthetic spectra were compared to solar observations with high spatial and spectral resolution, including new data collected with the CRISP instrument at the Swedish 1-m Solar Telescope between µ = 0.1 and µ = 1.0.

    Results. Our 3D non-LTE modeling of the Na I D1 resonance line at 5896 Å and the K I 7699 Å resonance line in the Sun is in good agreement with the observed CLV in the solar spectrum. Moreover, the simulated CLV curve for a Jupiter-Sun system inferred with a 3D non-LTE analysis shows significant differences from the one obtained from a 1D atmosphere. The latter does indeed tend to overestimate the amplitude of the transmission curve by a factor that is on the same order of magnitude as a planetary absorption depth (i.e., up to 0.2%).

    Conclusions. This work highlights the fact that to correctly characterize exoplanetary atmospheres, 3D non-LTE synthetic spectra ought to be used to estimate the stellar CLV effect in transmission spectra of solar-like planet hosts. Moreover, since different spectral lines show different CLV curves for the same geometry of the planet-star system, it is fundamental to model the CLV individually for each line of interest. The work will be extended to other lines and FGK-type stars, allowing for synthetic high-resolution spectra to mitigate the stellar contamination of low-resolution planetary spectra, for example, those drawn from JWST.

    Read more about 3D non-LTE modeling of the stellar center-to-limb variation for transmission spectroscopy studies

Show all publications by Gloria Canocchi at Stockholm University