Found 17 talks width keyword supernovae

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Tuesday December 20, 2011
IEEC, Spain

Abstract

Supernovae are at the heart of some of the most important problems of modern astronomy. To fully understand their importance and to enable their use as probes of stellar evolution throughout cosmic time, it is
absolutely essential to determine their stellar origins, i.e., their progenitors or progenitor systems. Even with over 5600 known SNe, we have only direct information about the progenitor star for a handful of explosions. Based on the statistics of 20 SNe II-P for which progenitors have been isolated or upper mass limits established, it has been derived a
more limited range of 8-17 solar masses for these stars, and it appears that all of these progenitors exploded in the RSG phase, as we would theoretically expect. However there has been no detection of a higher mass stars in the range 20-40 solar masses, which should be the most luminous and brightest stars in these galaxies. Therefore, I will present here the
results of our group in the analysis of Hubble Space Telescope (HST) and deep ground-based images, isolating the massive progenitor stars of several recent core-collapse supernovae.


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Friday March 25, 2011
University of Central Lancashire, UK

Abstract

Spectroscopic analysis of stellar populations is widely used to understand the history of many systems including globular clusters, nuclear star clusters, dwarf galaxies through to giant galaxies over a wide range of redshifts. In this talk I first explore aspects of stellar population fitting, focussing on the effects of interacting binary stars on the yields and hence the spectra of early-type galaxies. The second part of the talk concentrates on what we know about supernovae type Ia and the importance of understanding their contributions to the chemical evolution of galaxies and stellar populations.


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Thursday November 4, 2010
CEA, Service d'Astrophysique, France

Abstract

The so called "dark ages" of the universe began about 400.000 years after the Big Bang as matter cooled down and space became filled with neutral hydrogen for hundreds of millions years. How the Universe was heated and reionized during the first billion years after the Big Bang is a question of topical interest in cosmology. I will show that current theoretical models on the formation and collapse of primordial stars suggest that a large fraction of massive stars should have imploded, forming high-mass black hole X-ray binaries. Then, I will review the recent observations of compact stellar remnants in the near and distant universe that support this theoretical expectation, showing that the thermal (UV and soft X-rays) and non-thermal (hard X-rays, winds and jets) emission from a large population of stellar black holes in high mass binaries heated the intergalactic medium over large volumes of space, complementing the reionization by their stellar progenitors. Feedback from accreting stellar black holes at that epoch would have prevented the formation of the large quantities of low mass dwarf galaxies that are predicted by the cold dark matter model of the universe. A large population of black hole binaries may be important for future observations of gravitational waves as well as for the existing and future atomic hydrogen radio surveys of HI in the early universe.

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Monday May 17, 2010
Moscow State University and Sternberg Astronomical Institute, Russia

Abstract

The main goal of the MASTER-Net project is to produce a unique fast sky survey with all sky observed over a single night down to a limiting magnitude of 21. Such a survey will make it possible to address a number of fundamental problems: search for dark energy via the discovery and photometry of supernovae (including SNIa), search for exoplanets, microlensing effects, discovery of minor bodies in the Solar System, and space-junk monitoring. All MASTER telescopes can be guided by alerts, and we plan to observe prompt optical emission from gamma-ray bursts synchronously in several filters and in several polarization planes.

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Thursday October 1, 2009
Liverpool John Moores University, UK

Abstract

Long suspected on theoretical grounds and supported by tantalising observational evidence, the connection between supernovae and gamma-ray bursts was definitely established in 2003. Since then, a number of events have forced us to revise what we thought we knew about SNe and GRBs. This SN/GRB connection went from tentative to definitive, to maybe not, to maybe in most cases. I will briefly review the major milestones along this road and describe the situation as it is today.

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Wednesday November 5, 2008
Armagh Observatory, Northern Ireland

Abstract

Radiation-driven mass loss largely determines the life expectancy of massive stars. I will present our most recent mass-loss predictions for massive stars, which are obtained from Monte-Carlo multi-line radiative transfer calculations. I will show how these predictions are expected to change as a function of metallicity (and redshift!) and confront the results against data from the VLT FLAMES large programme of massive stars. Finally, I discuss some of the more intricate aspects of the physics of radiation-driven outflows, emphasizing the relevance for the rotational evolution of massive stars into the Luminous Blue Variable phase. This is shown to lead to some rather unexpected results... in particular for the progenitors of supernovae and gamma-ray bursts -- calling for some major paradigm shifts of even our most basic framework of massive star evolution.

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Thursday June 12, 2008
Liverpool John Moores University, UK

Abstract

I will present results from a survey of the star formation properties of nearby galaxies, using H alpha narrow-band imaging. The first half of the talk will cover the `expected' results of such a survey: how total star formation rates depend on galaxy morphology, the contribution of different types to the global star formation activity per unit volume of the nearby Universe, constraints on star formation histories, and indications of how stellar mass has been assembled in disks from the spatial distributions of young and old stars. The second half will look at some less expected spin-offs, including some surprising facts about the Magellanic Clouds, and new findings on progenitors of core-collapse supernovae.

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