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Informal Colloquium |
Caroline Gieser
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Max-Planck-Institut für Astronomie, Heidelberg
During high-mass star formation, fragmentation takes place on various
spatial scales from giant molecular clouds down to disk scales. At the
earliest evolutionary stages, high-mass protostars are still deeply
embedded within their parental molecular cloud and can be studied best
at high spatial resolution with interferometers at mm wavelengths. The
IRAM/NOEMA large program CORE allows us to analyze the physical and
chemical properties of a sample of luminous high-mass star-forming
regions. The 1 mm dust continuum of the sample shows a large diversity
of fragmentation properties. Using the spectral line emission, we are
able to determine the physical structure (temperature and density) and
molecular content of individual fragmented cores. Even though all
regions are classified to harbor high-mass protostellar objects, the
molecular content shows a high degree of complexity. By combining the
observed core properties, we are able to estimate chemical timescales
with the physical-chemical model MUSCLE. We find well-constrained
density and temperature profiles in agreement with theoretical
predictions. The molecular complexity in the core spectra can be
explained by an age spread that is then confirmed by our
physical-chemical modeling. The hot molecular cores show the greatest
number of emission lines, but we also find evolved cores in which most
molecules are destroyed and, thus, the spectra appear line-poor once
again. Currently, we are expanding our sample with ALMA 3 mm
observations of 11 additional high-mass star-forming regions at
different evolutionary stages - from infrared dark clouds to
ultra-compact HII regions - in order to further investigate the
evolution of the physical and chemical properties on core scales.