The evolution of a gas shell, swept by the supernova remnant of a massive first generation star, is studied with H_2 and HD chemistry taken into account. When a first-generation star explodes as a supernova, H_2 and HD molecules are formed in the swept gas shell and effectively cool the gas shell to temperatures of 32 K - 154 K. If the supernova remnant can sweep to gather the ambient gas, the gas shell comes to be dominated by its self-gravity, and hence, is expected to fragment. Our result shows that for a reasonable range of temperatures (200 K - 1000 K) of interstellar gas, the formation of second-generation stars can be triggered by a single supernova or hypernova
Very little is known about the physical processes which determined the end of star formation in glob...
The thermal and fragmentation properties of star forming clouds have important consequences on the c...
Context. The evolution of interstellar clouds of gas and dust establishes the prerequisites for star...
We show that the explosion of the first supernovae can trigger low-mass star formation via gravitati...
The dynamical and thermal evolution of a gas shell, swept by supernova in the first-collapsed pregal...
The first stars in the Universe are predicted to have been much more massive than the Sun. Gravitati...
We investigate molecular evolution in a star-forming core that is initially a hydrostatic starless c...
We have modeled the chemistry that occurs in the envelopes surrounding newborn stars as they are gra...
Context. The evolution of interstellar clouds of gas and dust establishes the prerequisites for star...
Primordial stars are formed from a chemically pristine gas consisting of hydrogen and helium. They a...
The complexity of physico-chemical models of star formation is increasing, with models that take int...
Context. Numerical simulations of star formation are becoming ever more sophisticated, incorporating...
The role of HD cooling in the formation of primordial objects is examined by means of a great number...
On galactic scales, the surface density of star formation appears to be well correlated with the sur...
Context. Anomalous surface abundances are observed in a fraction of the low-mass stars of Galactic g...
Very little is known about the physical processes which determined the end of star formation in glob...
The thermal and fragmentation properties of star forming clouds have important consequences on the c...
Context. The evolution of interstellar clouds of gas and dust establishes the prerequisites for star...
We show that the explosion of the first supernovae can trigger low-mass star formation via gravitati...
The dynamical and thermal evolution of a gas shell, swept by supernova in the first-collapsed pregal...
The first stars in the Universe are predicted to have been much more massive than the Sun. Gravitati...
We investigate molecular evolution in a star-forming core that is initially a hydrostatic starless c...
We have modeled the chemistry that occurs in the envelopes surrounding newborn stars as they are gra...
Context. The evolution of interstellar clouds of gas and dust establishes the prerequisites for star...
Primordial stars are formed from a chemically pristine gas consisting of hydrogen and helium. They a...
The complexity of physico-chemical models of star formation is increasing, with models that take int...
Context. Numerical simulations of star formation are becoming ever more sophisticated, incorporating...
The role of HD cooling in the formation of primordial objects is examined by means of a great number...
On galactic scales, the surface density of star formation appears to be well correlated with the sur...
Context. Anomalous surface abundances are observed in a fraction of the low-mass stars of Galactic g...
Very little is known about the physical processes which determined the end of star formation in glob...
The thermal and fragmentation properties of star forming clouds have important consequences on the c...
Context. The evolution of interstellar clouds of gas and dust establishes the prerequisites for star...
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