Calendar

Active galactic nuclei (AGN) are the  most powerful long standing phenomena in the universe. Among them, the most extreme sources display ultra relativistic particle jets which radiate over the full electromagnetic spectrum, from radio to very high energies (E > 100 GeV). The cosmological distances of these sources make very difficult to decipher the location and origin of their high energy emission, which remains one of the major not (fully) answered question of this research field.
I will show how the parsec-scale imaging from radio very-long-baseline-interferometry (VLBI) observations coupled to broadband spectral models and hydrodymamic jet simulations lead us toward and updated unification scheme of the jetted AGN phenomenon.

The properties of coronal mass ejections (CME) in the heliosphere is determined by a complex chain of processes. This presentation highlights this fact by reviewing CME’s (1) intrinsic properties set at the Sun (e.g., orientation, velocity), (2) processes that may occur during eruption and propagation (e.g., shocks, confinement or magnetic erosion), and (3) in the specific interaction with the planet (e.g., magnetic properties, preconditioning mechanisms), and which together determine the CME’s actual impact. The relative importance of these processes is discussed, as well as implications at planets other than the Earth, including exoplanetary systems.

Benoit Lavraud
IRAP, CNRS, CNES, Université de Toulouse, France

Most stars form in clusters within giant molecular clouds (GMCs). However, the processes that induce the collapse and fragmentation of GMCs into star-forming clumps and cores are poorly understood. While the effects of turbulence and gravity have long been studied, the role of magnetic fields in the star formation process is only now becoming clear. In this talk, I present simulations and observations of forming star clusters to shed light on connections with their environments. First, I introduce magnetohydrodynamics simulations of GMCs evolving quiescently vs. those embedded in converging flows. The filamentary gas structures and star formation properties resulting from each scenario are quantified with particular attention given to the role of magnetic fields. These results are then compared with polarization studies as well as recent ALMA observations of massive star-forming clumps. Finally, I discuss work being done in the ongoing ALMA-IMF large program towards determining the origin of the stellar initial mass function (IMF).

Star formation is a multi-physics, multi-scale process. the physical scales that are involved vary by 10 orders of magnitude, from the size of entire galaxies down to the size of the Solar system. The physical processes that are involved include gravity, turbulence, magnetic fields, radiation, chemical reactions, and cooling and heating processes. This multiplicity of processes and scales can generate a significant amount of variation in the outcome of star formation from galaxy to galaxy and from region to region within galaxies, in particular in terms of key quantities such as the stellar initial mass function (IMF), the star formation rate (SFR), and the star formation efficiency (SFE). I will present a brief overview of the current status of observations for the IMF and the SFR in the Milky Way and in nearby galaxies and discuss theoretical ideas and numerical simulations that attempt to reproduce these observations.

In contrast to the water-poor planets of the inner Solar System,
stochasticity during planetary formation and order of-magnitude deviations
in exoplanet volatile contents suggest that rocky worlds engulfed in thick
volatile ice layers are the dominant family of terrestrial analogues among
the extrasolar planet population.
Here we use numerical models of planet formation, evolution and interior
structure to show that a planet’s bulk water fraction and radius are
anticorrelated with initial 26Al levels in the planetesimal-based
accretion framework. The heat generated by this short-lived radionuclide
rapidly dehydrates planetesimals before their accretion onto larger
protoplanets and yields a system-wide correlation of planetary bulk water
abundances, which, for instance, can explain the lack of a clear orbital
trend in the water budgets of the TRAPPIST-1 planets.
Qualitatively, our models suggest two main scenarios for the formation of
planetary systems: high-26Al systems, like our Solar System, form small,
water-depleted planets, whereas those devoid of 26Al predominantly form
ocean worlds. For planets of similar mass, the mean planetary transit
radii of the ocean planet population can be up to about 10% larger than
for planets from the 26Al-rich formation scenario.

Galaxy history is marked by a peak of star formation ten billion years ago and a subsequent drop of the star formation rate (SFR) by an order of magnitude. To understand this evolution, it is crucial to probe the gas reservoirs from which stars are formed. With programs observing the molecular gas phase in typical star-forming galaxies at different epochs, I will present how the cosmic evolution of the SFR is mainly driven by that of the molecular gas fraction. The depletion time associated to star formation indeed only weakly changes with redshift, both at galactic and at sub-galactic scales. I will show that the molecular gas content during the winding-down of star formation does not seem to correlate with morphology, suggesting an ongoing supply of molecular gas to compensate for star formation while bulges grow. In contrast, molecular gas reservoirs can be dramatically depleted in extreme environments such as cluster centres. While structure formation is primarily driven by dark matter (DM) dynamics in ΛCDM cosmology, gas processes can in turn affect the DM distribution at galactic scales. Using theoretical modelling and simulations, I will discuss how outflow episodes and gas density fluctuations induced by stellar feedback can expand both the DM and the stellar distributions and hence provide a simple understanding of the formation of DM halo cores and ultra-diffuse galaxies.

Inverse methods have become a fundamental analysis technique for modelling exoplanetary atmospheres. This technique explores a variety of potential bulk and atmospheric model parameters that combine to best-fit an observed spectrum. TauREx (Tau Retrieval of Exoplanets) is a Bayesian retrieval suite designed to be applied to spectroscopic observations of extrasolar planetary atmospheres. We have adapted TauREx for analysis of near-infrared spectrophotometry from a variety of directly-imaged gas giant exoplanets and brown dwarfs. This includes the HR 8799 system, Beta Pic b, 51 Eri b, and PSO 318 observed using instruments such as SPHERE, GPI and GNIRS. We also perform retrieval analysis on L and T dwarf spectra from the IRTF SpeX Spectral Library. This analysis returns estimates for target mass, radius, surface gravity, temperature-pressure structure and cloud properties, as well as confirming and constraining the presence of a variety of molecular species including H2O, CO and CH4. Inverse techniques have mainly been applied to transit spectroscopy in the past and as a result, this is the first application of retrieval analysis to many directly-imaged targets. This project aims to help bridge directly-imaged exoplanet observations with robust, efficient and precise characterisation. The development and adaptation of this retrieval tool is timely and relevant given the upcoming launch of JWST. In this talk I will present a summary of the novel retrieval results from this project.

Interstellar complex organic molecules (COMs) were first detected toward so called hot cores around high-mass protostars. The high temperatures that prevail in these regions boost gas-phase chemical complexity via thermal desorption of the complex species trapped in dust-grain ice-mantles. The COMs detected in the gas-phase are excellent diagnostic tools of the physical conditions of their environment. In this context, the high sensitivity and high angular resolution provided by the Atacama Large Millimeter/submillimeter Array (ALMA) is a strong asset to investigate the physical and chemical structure of the envelope of young high-mass protostars. I will present the results from the analysis of two ALMA projects, the 3mm imaging line survey Exploring Molecular Complexity with ALMA (EMoCA) and the Search for high-mass Protostars with ALMA up to Kiloparsec Scales (SPARKS), to show that hot cores exhibit a great diversity in their chemical composition and physical structure. I will also show how by combining observations with astrochemical models we can study the building-up of chemical complexity toward high-mass star forming regions.

The formation of stars in galaxies is regulated by the amount of cold gas that can fragment into small clumps. Interstellar dust grains play a key role in this process shielding light  and providing sites for molecule formation. Dust grains are created and destroyed during galaxy evolution and how the current dust content relates to other internal properties, and to the environment, has been the aim of recent infrared survey and studies. I will outline the basic scaling relations involving dust and gas in star forming galaxies as well as some surprising recent results that suggest possible variations of the grain physical properties with local conditions in galaxy disks.  

Edvige Corbelli

INAF-Osservatorio di Arcetri

(Firenze – Italy)