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Main Authors: Arroyo-Chávez, Griselda, Kong, Shuo, Vázquez-Semadeni, Enrique
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.06990
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author Arroyo-Chávez, Griselda
Kong, Shuo
Vázquez-Semadeni, Enrique
author_facet Arroyo-Chávez, Griselda
Kong, Shuo
Vázquez-Semadeni, Enrique
contents Different models of filament formation predict distinct patterns of angular momentum redistribution toward embedded cores, set by the underlying velocity-field structure, which can set the initial conditions for a preferential orientation between protostellar outflows and filaments. However, the absence of a dominant alignment in observations keeps this connection open to debate. We investigate whether gravity-driven longitudinal flows along filaments can redistribute angular momentum (AM) toward collapse centers and influence outflow-filament alignment. To this end, we analyze the distributions of 3D and 2D-projected angles between sink angular momentum vectors and host filament orientations in an SPH simulation of giant molecular cloud and filament formation. We also characterize the filament velocity field by measuring the angles between SPH particle velocity vectors and filament axes, and the degree of convergent flow toward filament density peaks. No preferred alignment between the sinks' AM and the filament direction is found at early evolutionary stages, neither in 3D nor in 2D. Later, however, a predominantly perpendicular configuration emerges in 3D. Tracking individual sinks indicates that this alignment is not primordial but develops as gravity strengthens. In individual filaments, the onset of perpendicular alignment coincides with the development of convergent longitudinal flows. Finally, we estimate the minimum fraction of perpendicular 3D angles required to reveal a perpendicular 2D alignment for a given sample size. While longitudinal flows develop over extended timescales, once established, they can rapidly reorient the angular momentum vector of the sinks, enabling perpendicular alignments to arise within typical outflow lifetimes.
format Preprint
id arxiv_https___arxiv_org_abs_2603_06990
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Effect of gravity-driven longitudinal flows in filaments on angular momentum transport to embedded cores
Arroyo-Chávez, Griselda
Kong, Shuo
Vázquez-Semadeni, Enrique
Astrophysics of Galaxies
Different models of filament formation predict distinct patterns of angular momentum redistribution toward embedded cores, set by the underlying velocity-field structure, which can set the initial conditions for a preferential orientation between protostellar outflows and filaments. However, the absence of a dominant alignment in observations keeps this connection open to debate. We investigate whether gravity-driven longitudinal flows along filaments can redistribute angular momentum (AM) toward collapse centers and influence outflow-filament alignment. To this end, we analyze the distributions of 3D and 2D-projected angles between sink angular momentum vectors and host filament orientations in an SPH simulation of giant molecular cloud and filament formation. We also characterize the filament velocity field by measuring the angles between SPH particle velocity vectors and filament axes, and the degree of convergent flow toward filament density peaks. No preferred alignment between the sinks' AM and the filament direction is found at early evolutionary stages, neither in 3D nor in 2D. Later, however, a predominantly perpendicular configuration emerges in 3D. Tracking individual sinks indicates that this alignment is not primordial but develops as gravity strengthens. In individual filaments, the onset of perpendicular alignment coincides with the development of convergent longitudinal flows. Finally, we estimate the minimum fraction of perpendicular 3D angles required to reveal a perpendicular 2D alignment for a given sample size. While longitudinal flows develop over extended timescales, once established, they can rapidly reorient the angular momentum vector of the sinks, enabling perpendicular alignments to arise within typical outflow lifetimes.
title Effect of gravity-driven longitudinal flows in filaments on angular momentum transport to embedded cores
topic Astrophysics of Galaxies
url https://arxiv.org/abs/2603.06990