Context. Observations indicate that stars generally lose their protoplanetary discs on a timescale of about 5 Myr. Which mechanisms are responsible for the disc dissipation is still debated. Aims. Here we investigate the movement through an ambient medium as a possible cause of disc dispersal. The ram pressure exerted by the flow can truncate the disc and the accretion of material with no azimuthal angular momentum leads to further disc contraction. Methods. We derive a theoretical model from accretion disc theory that describes the evolution of the disc radius, mass, and surface density profile as a function of the density and velocity of the ambient medium. We test our model by performing hydrodynamical simulations of a pr...
Context. To form metre-sized pre-planetesimals in protoplanetary discs, growing grains have to decou...
In this paper we consider the effect of the direct ionizing stellar radiation field on the evolu-tio...
How protoplanetary discs evolve remains an unanswered question. Competing theories of viscosity and ...
Context. Observations indicate that stars generally lose their protoplanetary discs on a timescale o...
Context. Stars are generally born in clustered stellar environments, which can affect their subseque...
Context. Understanding how accretion proceeds in proto-planetary discs, and more generally, understa...
Context. Planets form in protoplanetary discs. Their masses, distribution, and orbits sensitively de...
Protoplanetary discs are a natural consequence of the star formation process and as such are ubiquit...
textabstractObservations indicate that the dispersal of protoplanetary discs in star clusters occurs...
Observations indicate that the dispersal of protoplanetary discs in star clusters occurs on time sca...
Context. The properties of protoplanetary discs determine the conditions for planet formation. In ad...
The gaseous component of protoplanetary discs has traditionally been described as undergoing viscous...
Protoplanetary disks dissipate rapidly after the central star forms, on time-scales comparable to th...
Surveys of star-forming regions reveal that the dust mass of protoplanetary discs decreases by sever...
Context. To form metre-sized pre-planetesimals in protoplanetary discs, growing grains have to decou...
In this paper we consider the effect of the direct ionizing stellar radiation field on the evolu-tio...
How protoplanetary discs evolve remains an unanswered question. Competing theories of viscosity and ...
Context. Observations indicate that stars generally lose their protoplanetary discs on a timescale o...
Context. Stars are generally born in clustered stellar environments, which can affect their subseque...
Context. Understanding how accretion proceeds in proto-planetary discs, and more generally, understa...
Context. Planets form in protoplanetary discs. Their masses, distribution, and orbits sensitively de...
Protoplanetary discs are a natural consequence of the star formation process and as such are ubiquit...
textabstractObservations indicate that the dispersal of protoplanetary discs in star clusters occurs...
Observations indicate that the dispersal of protoplanetary discs in star clusters occurs on time sca...
Context. The properties of protoplanetary discs determine the conditions for planet formation. In ad...
The gaseous component of protoplanetary discs has traditionally been described as undergoing viscous...
Protoplanetary disks dissipate rapidly after the central star forms, on time-scales comparable to th...
Surveys of star-forming regions reveal that the dust mass of protoplanetary discs decreases by sever...
Context. To form metre-sized pre-planetesimals in protoplanetary discs, growing grains have to decou...
In this paper we consider the effect of the direct ionizing stellar radiation field on the evolu-tio...
How protoplanetary discs evolve remains an unanswered question. Competing theories of viscosity and ...