This week's PhD colloquia are highlighted.
|09/02||11:00||Simulating the birth environment of circumstellar discs|
Circumstellar discs are the reservoirs of gas and dust that surround young stars and have the potential to become planetary systems. Their evolution will determine the time and material available to form planets. Studying the evolution of circumstellar discs can then help us understand planet formation and the diversity of observed planetary systems. These discs develop almost immediately after star formation, as a direct consequence of the collapse of a molecular cloud and angular momentum conservation. Their surroundings are rich in gas and neighbouring stars, which can be hostile to the discs and affect their evolution in different ways: dynamical encounters with nearby stars can truncate the discs; stellar winds and supernovae explosions can truncate, tilt, or completely destroy the discs; and the presence of bright, massive stars in the vicinity of circumstellar discs can heat their surface enough to evaporate mass from them. This process, known as external photoevaporation, is arguably one of the most important environmental mechanisms in depleting mass from young circumstellar discs. In this talk I will present the results obtained during my PhD research. My work consisted in simulating the early evolution of circumstellar discs in star clusters and the effects of the environment, in particular truncations due to close encounters and photoevaporation. My results show that photoevaporation is extremely efficient in removing mass from the discs, greatly limiting the amount of material and time available to form planets.
|Francisca Concha-Ramirez||Leiden Observatory|
|23/02||11:00||Cold gas in distant galaxies|
The formation and evolution of galaxies is fundamentally driven by the formation of new stars out of cold gas. Observations of young stars in distant galaxies in the early universe, such as we can see in the Hubble Ultra Deep Field, have unveiled how the cosmic star formation rate density evolves. Yet, while the effect of star formation (the young stars) has been mapped in ever-increasing detail, the cause (the cold molecular gas that fuels star formation) has been elusive. In this talk, I will present my thesis work, that involved an observational study of the cold interstellar medium of distant galaxies in the early universe, using the most sensitive submillimeter telescope to date, the Atacama Large Millimeter Array, together with new integral-field spectrographs, such as the Multi Unit Spectroscopic Explorer on the Very Large Telescope. I will present the physical properties of star-forming galaxies and their molecular gas reservoirs, and describe the evolution of the cosmic molecular gas density; the fuel for star formation.
|Leindert Boogaard||Leiden Observatory|
|02/03||Feedback by massive stars: Velocity-resolved [CII] observations of the Horsehead Nebula and Orion's Dragon|
Stellar feedback is a crucial ingredient in the evolution of galaxies. Massive stars disrupt their natal molecular clouds and perturb the ambient interstellar medium, not only when they explode as supernovae but also during their lifetimes by stellar winds and radiation. The irradiated, heated, and stirred gas cools through the emission of fine-structure lines. The far-infrared fine-structure line of ionized carbon is the dominant coolant of warm neutral gas and has been suggested as a powerful tracer of the star-formation rate (a derivative of stellar feedback) in distant galaxies. In this talk I present my thesis work, that explores the origins of the [CII] emission and quantifies stellar feedback observationally in local samples. I have used high-resolution (both spectral and angular) observations of the [CII] line obtained with the upGREAT instrument onboard the Stratospheric Observatory for Infrared Astronomy (SOFIA) of the Horsehead Nebula and the Orion Nebula at the surface of the Orion molecular cloud. This nearby template star-forming region allows to study physical properties of the irradiated gas and to precisely determine the amount of kinetic energy deposited in the expanding bubbles surrounding the massive stars.
|14:00||Protostellar jets and planet-forming disks: witnessing the formation of Solar System analogues with interferometry|
I will present my thesis results, focusing on characterizing components of young protostellar systems, most notably their jets and disks. Using observations with the ALMA and VLA interferometers, we observed the environments where the first stages of star and planet formation occur. We revealed information on crucial chemical tracers of various protostellar systems components. With a particular focus on molecular jets, I show differentiation in chemical composition between the fast jet and the low-velocity outflow. For the first time, we were able to compare dust masses of young disks with older disks. By comparing this information with masses of the extrasolar planets detected so far, I showed that the solid cores of gas giants must form in the first 0.1 Myr of stellar life. That is an important time constraint that pushes the onset of planet formation earlier and highlights the importance of characterization of the youngest protostars in understanding the origin of Solar System and Earth.
|Lukasz Tychoniec||Leiden Observatory|
|01/06||11:00||Focal-plane wavefront sensors for direct exoplanet imaging|
The direct imaging and characterization of rocky exoplanets around nearby stars with extremely large telescopes is one of the goals of modern astronomy. For ground-based telescopes this is very challenging due to uncorrected wavefront aberrations caused by the Earth's atmosphere, the telescope's structure and optics in the instrument. To his end, extreme adaptive optics (xAO) systems have been developed, which have been successful in correcting atmospheric wavefront errors. However, current xAO systems have trouble measuring aberrations caused by optics downstream of the wavefront sensor and the "low-wind effect", which are among the current limitations in direct exoplanet imaging. In this colloquium I will show how I use focal-plane wavefront sensing to measure and correct these aberrations. I will start with an introduction on focal-plane wavefront sensing and discuss its specific challenges. New focal-plane wavefront sensors are presented that are fully integrated with other subsystems to enable highly efficient science observations. Finally, I will show successful on-sky tests of these focal-plane wavefront sensors with the SCExAO instrument at the Subaru telescope.
|15/06||11:00||It’s just a phase: high-contrast imaging with patterned liquid-crystal phase plates to facilitate characterization of exoplanets|
The focus of exoplanet research is transitioning from finding exoplanets to characterizing their atmospheres. High-contrast imaging (HCI) enables the study of resolved exoplanet light through spectroscopy, polarimetry, or even photometric variability. These measurements require optics that operate over a broad wavelength range and can accommodate flexible designs. In this talk I will demonstrate how liquid-crystal (LC) optics can meet these requirements and be used to improve the integration of HCI subsystems to facilitate detailed exoplanet characterization. First, I discuss the design, performance, and future development of the liquid-crystal vector-apodizing phase plate (vAPP) coronagraph, five of which have been installed in different instruments since 2016. In addition, I summarize how the vAPP can be adapted for wavefront sensing or improved exoplanet photometry. By using the achromatic nature of the vAPP in combination with the LBT/ALES integral field spectrograph, I obtained the first ever thermal infrared spectrum of the inner three HR 8799 planets. Finally, I show applications of LC technology for aperture masking with improved throughput and low spectral resolution, as well as a LC Zernike wavefront sensor with extreme sensitivity that simultaneously measures phase and amplitude aberrations.
|David Doelman||Leiden Observatory|