Add to ORKGContext.Massive stars form in dense and massive molecular cores. The exact formation mechanism is unclear, but it is possible that some massive stars are formed by processes similar to those that produce the low-mass stars, with accretion/ejection phenomena occurring at some point of the evolution of the protostar. This picture seems to be supported by the detection of a collimated stellar wind emanating from the massive protostar IRAS 16547-4247. A triple radio source is associated with the protostar: a compact core and two radio lobes. The emission of the southern lobe is clearly non-thermal. Such emission is interpreted as synchrotron radiation produced by relativistic electrons locally accelerated at the termination point of a thermal j...
In recent years, massive protostars have turned out to be a possible population of high-energy emitt...
Colliding winds of massive binaries have long been considered as potential sites of non-thermal high...
In recent years, massive protostars have turned out to be a possible population of high-energy emitt...
Context.Massive stars form in dense and massive molecular cores. The exact formation mechanism is un...
Recent radio observations support a picture for star formation where there is accretion of matter on...
Context. Massive protostars have associated bipolar outflows with velocities of hundreds of km s-1. ...
Massive protostars have associated bipolar outflows with velocities of hundreds of km s-1. Such outf...
Protostellar jets are present in the later stages of the stellarformation. Non-thermal radio emissio...
The young stellar object IRAS 16547-4247, identified with a massive protostar, presents a highly col...
Massive protostars have associated bipolar outflows with velocities of hundreds of km s-1. Such outf...
Thermal radio and X-ray emission has been traditionally associated with the formation of stars. Howe...
We study the interaction of early-type stars with the jets of active galactic nuclei. A bow-shock wi...
Dense populations of stars surround the nuclear regions of galaxies. In active galactic nuclei, thes...
In recent years, massive protostars have turned out to be a possible population of high-energy emitt...
Colliding winds of massive binaries have long been considered as potential sites of non-thermal high...
In recent years, massive protostars have turned out to be a possible population of high-energy emitt...
Context.Massive stars form in dense and massive molecular cores. The exact formation mechanism is un...
Recent radio observations support a picture for star formation where there is accretion of matter on...
Context. Massive protostars have associated bipolar outflows with velocities of hundreds of km s-1. ...
Massive protostars have associated bipolar outflows with velocities of hundreds of km s-1. Such outf...
Protostellar jets are present in the later stages of the stellarformation. Non-thermal radio emissio...
The young stellar object IRAS 16547-4247, identified with a massive protostar, presents a highly col...
Massive protostars have associated bipolar outflows with velocities of hundreds of km s-1. Such outf...
Thermal radio and X-ray emission has been traditionally associated with the formation of stars. Howe...
We study the interaction of early-type stars with the jets of active galactic nuclei. A bow-shock wi...
Dense populations of stars surround the nuclear regions of galaxies. In active galactic nuclei, thes...
In recent years, massive protostars have turned out to be a possible population of high-energy emitt...
Colliding winds of massive binaries have long been considered as potential sites of non-thermal high...
In recent years, massive protostars have turned out to be a possible population of high-energy emitt...