Language: English
Abstract:
The formation of circumstellar disks is investigated using three-dimensional resistive magnetohydrodynamic simulations in which the initial prestellar cloud has a misaligned rotation axis with respect to the magnetic field. We examine the effects of (i) the initial angle difference between the global magnetic field and the cloud rotation axis and (ii) the ratio of the thermal to gravitational energy. We study 16 models in total and calculate the cloud evolution until ∼5000 yr after protostar formation. Our simulation results indicate that an initial nonzero promotes disk formation but tends to suppress outflow driving for models that are moderately gravitationally unstable. In these models, a large-sized rotationally supported disk forms and a weak outflow appears, in contrast to a smaller disk and strong outflow in the aligned case.
(This talk will be given online. Details will be announced via e-mail.)
Language: English
Abstract:
Finding new aspects of the universe through observations using own developed instruments is the most exciting experience for observational astronomers. Although the telescopes of big projects like ALMA provide opportunities to tackle excellent sciences, there is some room to flourish as well for smaller projects such as single dish telescopes in radio astronomy because they have advantages especially on their wider field of view. In this seminar, I introduce two projects in which I have been involved. One is the 1.85-m mm-submm telescope developed by Osaka Prefecture University aiming to observe CO(2-1) at 230 GHz (1.3 mm). Thus far, more than 1800 deg2 are mapped including the Galactic plane and nearby molecular clouds, and the project provides a good reference of the ratio between CO(1-0) and CO(2-1) toward the giant molecular clouds. The other is the FUGIN project which is a CO(1-0) survey toward the Galactic plane using the FOREST receiver (4-beam) installed on Nobeyama 45-m telescope. By grace of its high dynamic range (wide area with high resolution) data, we find that most of the giant molecular clouds associated with the high mass star formation region experienced cloud-cloud collision. Finally, I briefly introduce the latest activities on developments of future multi-beam receivers.
(This talk will be given online. Details will be announced via e-mail.)
Language: Japanese (with English slide)
Abstract: Carbon is one of the major atoms in the Universe. It is valuable to examine carbon atoms and carbon-bearing molecules in the various interstellar environment to gain a deep understanding of interstellar chemistry. Emission lines from a neutral carbon atom ([CI]) are observed in the high-frequency ranges (492, 809 GHz). Since excellent atmospheric conditions are required in high-frequency observations, intensive studies of [CI] have been difficult before the ALMA era. In this talk, I will talk about two recent studies of [CI] with ALMA and ASTE in the different interstellar environments in our Galaxy (rho Oph A PDR and gamma-ray SNR W51C). Based on the results, I will discuss the origins of the [CI] emission in a star-forming region and the effects of cosmic-ray on interstellar chemistry.
(This talk will be given online. Details will be announced via e-mail.)
Language: English
Abstract: Studying young exoplanets is important because they inhabit a very important part of the exoplanet evolutionary timescale where several yet unknown processes are expected to shape their final outcome. However, finding and characterizing transiting exoplanets orbiting young stars is notoriously difficult. This is due to intrinsic high stellar activity in young stars that induces photometric variations and radial velocity jitter often a few orders of magnitude larger than the planet signal. This problem is compounded by the fact that most of the young stars usually reside in star clusters or moving groups where the false positive rate is high due to the crowded field. Despite the small sample of young planets discovered from the K2 mission however, there is tentative evidence that the planetʼs size depends with the host starʼs age. To confidently corroborate or refute such trends and to have a complete understanding on how exoplanets form and evolve from birth to maturity, the community needs a statistically significant sample of transiting planets orbiting bright young stars. As the TESS mission continues to survey the sky until 2022, new transiting planets around young stars will be discovered. The brightness of the host star would facilitate precise measurements of the fundamental parameters of the host stars and planets which in turn lead to better models to constrain their bulk density and atmospheric composition.
(This talk will be given online. Details will be announced via e-mail.)
Language: English
Abstract:
Neutrinos are guaranteed observable from the next Galactic supernova (SN). Optical lights and gravitational waves are also observable but can be difficult to observe if SN location in the galaxy and the explosion details are not suitable. The key to the next SN observation will be understanding various physical quantities using neutrinos first and then connecting them to other signals. In this seminar, I will introduce our current research on neutrino observation, particularly on long-time evolution. I will discuss how we can use neutrinos to determine the mass and radius of neutron stars that form in supernova explosions, which would be useful in probing other physics such as the explosion mechanism with other messengers.
(This talk will be given online. Details will be announced via e-mail.)
Language: Japanese (with English slide)
Abstract: Star formation activity in many barred galaxies is significantly different between in arms and in bars. In the arms, HII regions are associated with dust lanes, and giant molecular clouds (GMCs) coexist with the dust lanes. However, massive star formation is notably absent in the bars: Prominent HII regions are often not seen, while there are remarkable dust lanes along the bar which implies the existence of GMCs. Physical mechanisms which could suppress star formation in bar regions have been long debated and fall into the following three scenarios recently: (1) Gravitationally unbound molecular clouds in bar regions. (2) A large amount of diffuse molecular gases in bar regions. (3) Fast cloud-cloud collisions in bar regions. To unveil which of the scenarios is the most dominant cause for the suppression, we focus on the nearest strongly barred galaxy NGC 1300 where the massive star formation in the bar regions is remarkably suppressed compared to the arm regions. In this seminar, I will talk about the examination results for each scenario by CO observations using ALMA and Nobeyama 45-m telescope and discuss the cause of the star formation suppression.
(This talk will be given online. Details will be announced via e-mail.)
Language: Japanese (with English slide)
Abstract:
It is well known that there is a strong correlation between star formation activity and morphology in nearby galaxies. One possible explanation for this correlation is the influence of galaxy morphology on star formation activity. For example, Martig et al. (2009) has proposed "morphological quenching", in which star formation efficiency is reduced in early-type galaxies. However, its influence on galaxy evolution has not been clarified observationally. In this talk, I will present the results of a study of the difference in star formation activity due to the difference in morphology (disk- or bulge-dominated) using observations with Nobeyama45m and CO(1-0) data from xCOLDGASS. I will also introduce my recent work on the relationship between morphology and star formation using MaNGA, an IFU survey, data.
(This talk will be given online. Details will be announced via e-mail.)
Language: English
Abstract:
The link between the intergalactic medium (IGM) and galaxies is key to understand the evolution of baryonic matter and galaxies. In fact, several observational studies have confirmed the connection between the IGM HI and galaxies up to several tens comoving Mpc. However, understanding the variations on the IGM-galaxy connection over galactic properties, such as mass, SFR, and galaxy population, is still limited. Motivated by this, we have studied the IGM-galaxy connection and its dependence on those galactic parameters to shed more light on the link using both simulations and observations. In this talk, I will present the observational results obtained from Lyα forest tomography named the CLAMATO (Lee et al. 2016, 2018). I will also discuss the change of the IGM-galaxy connection in terms of galaxy evolution indicated from our results.
(This talk will be given online. Details will be announced via e-mail.)
Language: English
Abstract:
Binary black hole (BBH) mergers in dense stellar systems like globular clusters (GCs) are important sources for the gravitational waves detected by Advanced LIGO. Star-by-star N-body simulation is the most reliable method to understand the formation rate, mass ratio and orbital parameters of these BBHs. But it is very time-consuming to produce such a model because of the expensive computing. To overcome this bottleneck, I have developed a high-performance N-body code, PeTar. It is the fastest code for modelling massive star clusters with a large fraction of binaries. Using PeTar, we carried out a series of N-body models for massive star clusters, and found that the initial mass function significantly affects the long-term evolution of GCs and properties of BBH mergers, while primordial binaries have a weak influence. For low-mass open clusters with tidal streams, the stochastic sampling of IMF makes it impossible to predict their long-term evolution. In addition, we implement PeTar in a hydrodynamic code, Asura-bridge, which allows us to study the star cluster formation with the complexity from binary dynamics, gas and feedback of massive stars. With the benefit of highly accurate binary dynamics from PeTar, we found when massive stars form, the violent close interaction can easily eject them from the birth place and significantly affect the surrounding star formation. This may explain the multiple populations discovered in young star clusters like Orion nebular cluster. In summary, the PeTar code opens a new window to solve a variety of challenging N-body problems.
(This talk will be given online. Details will be announced via e-mail.)