Your search keyword '"Enrique Vázquez-Semadeni"' showing total 3 results

1. ENERGY BUDGET OF FORMING CLUMPS IN NUMERICAL SIMULATIONS OF COLLAPSING CLOUDS.

Author

Vianey Camacho, Enrique Vázquez-Semadeni, Javier Ballesteros-Paredes, Gilberto C. Gómez, S. Michael Fall, and M. Dolores Mata-Chávez

Subjects

*ENERGY budget (Geophysics), *MOLECULAR clouds, *INTERSTELLAR molecules, *HIGH-velocity clouds (Astrophysics), *ENERGY balance mass spectrometers

Abstract

We analyze the physical properties and energy balance of density enhancements in two SPH simulations of the formation, evolution, and collapse of giant molecular clouds. In the simulations, no feedback is included, so all motions are due either to the initial decaying turbulence or to gravitational contraction. We define clumps as connected regions above a series of density thresholds. The resulting full set of clumps follows the generalized energy equipartition relation, , where is the velocity dispersion, R is the “radius,” and Σ is the column density. We interpret this as a natural consequence of gravitational contraction at all scales rather than virial equilibrium. Nevertheless, clumps with low Σ tend to show a large scatter around equipartition. In more than half of the cases, this scatter is dominated by external turbulent compressions that assemble the clumps rather than by small-scale random motions that would disperse them. The other half does actually disperse. Moreover, clump sub-samples selected by means of different criteria exhibit different scalings. Sub-samples with narrow Σ ranges follow Larson-like relations, although characterized by their respective values of Σ. Finally, we find that (i) clumps lying in filaments tend to appear sub-virial, (ii) high-density cores ( cm3) that exhibit moderate kinetic energy excesses often contain sink (“stellar”) particles and the excess disappears when the stellar mass is taken into account in the energy balance, and (iii) cores with kinetic energy excess but no stellar particles are truly in a state of dispersal. [ABSTRACT FROM AUTHOR]

Published

2016

2. HIERARCHICAL GRAVITATIONAL FRAGMENTATION. I. COLLAPSING CORES WITHIN COLLAPSING CLOUDS.

Author

Raúl Naranjo-Romero, Enrique Vázquez-Semadeni, and Robert M. Loughnane

Subjects

*CLOUDS, *GRAVITY, *ATMOSPHERIC temperature, *VELOCITY, *HYDROSTATIC pressure

Abstract

We investigate the Hierarchical Gravitational Fragmentation scenario through numerical simulations of the prestellar stages of the collapse of a marginally gravitationally unstable isothermal sphere immersed in a strongly gravitationally unstable, uniform background medium. The core developes a Bonnor–Ebert (BE)-like density profile, while at the time of singularity (the protostar) formation the envelope approaches a singular-isothermal-sphere (SIS)-like r−2 density profile. However, these structures are never hydrostatic. In this case, the central flat region is characterized by an infall speed, while the envelope is characterized by a uniform speed. This implies that the hydrostatic SIS initial condition leading to Shu's classical inside-out solution is not expected to occur, and therefore neither should the inside-out solution. Instead, the solution collapses from the outside-in, naturally explaining the observation of extended infall velocities. The core, defined by the radius at which it merges with the background, has a time-variable mass, and evolves along the locus of the ensemble of observed prestellar cores in a plot of M/MBE versus M, where M is the core's mass and MBE is the critical BE mass, spanning the range from the “stable” to the “unstable” regimes, even though it is collapsing at all times. We conclude that the presence of an unstable background allows a core to evolve dynamically from the time when it first appears, even when it resembles a pressure-confined, stable BE-sphere. The core can be thought of as a ram-pressure confined BE-sphere, with an increasing mass due to the accretion from the unstable background. [ABSTRACT FROM AUTHOR]

Published

2015

3. ERRATUM: “THE FREE-FALL TIME OF FINITE SHEETS AND FILAMENTS” (2012, ApJ, 744, 190).

Author

Jesús A. Toalá, Enrique Vázquez-Semadeni, and Gilberto C. Gómez

Subjects

*ACCELERATION (Mechanics), *CLOUDS

Abstract

A correction to the article "The Free-Fall Time of Finite Sheets and Filaments" by Jesús A. Toalá et al., which appeared in the July 23, 2015 issue is presented.

Published

2015