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Main Authors: Patiño, Naiara, Calvet, Nuria, Magris, Gladis, Micolta, Marbely, Thanathibodee, Thanawuth, Waters, Thomas K., Colmenares, María José
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.24807
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author Patiño, Naiara
Calvet, Nuria
Magris, Gladis
Micolta, Marbely
Thanathibodee, Thanawuth
Waters, Thomas K.
Colmenares, María José
author_facet Patiño, Naiara
Calvet, Nuria
Magris, Gladis
Micolta, Marbely
Thanathibodee, Thanawuth
Waters, Thomas K.
Colmenares, María José
contents Magnetospheric accretion is the paradigm for accretion in Classical T-Tauri Stars (CTTS). However, the standard, one-flow magnetospheric accretion model fails to replicate important characteristics such as the observed Balmer decrements. We address this limitation by adopting a model with two axisymmetric magnetospheric accretion flows of different accretion rates and geometries. We calculate the fluxes of the hydrogen $H_α$, $H_β$, and $H_γ$ lines of each flow with the magnetospheric accretion model and use Bayesian statistics to fit the Balmer line fluxes of 139 CTTS in the Orion OB1b subassociation, and in the Upper Scorpius, Lupus and Chamaeleon I star-forming regions. We find that the Balmer decrements and line fluxes can be fitted by two distinct but coexisting flows: a compact, high accretion rate flow, close to the star and narrow (mean inner radius $R_i \sim 2.9 R_*$ and mean width $ΔR \sim 0.7 R_*$), covering a few percent of the emitting area, and a more spread out flow, thicker ($ΔR \sim 1.2 R_*$), and larger ($R_i \sim 3.7 R_*$), with lower accretion rate, encompassing the rest of the emitting area. The two-flow model can also reproduce the empirical correlation between the luminosity in $H_α$ and the accretion luminosity. Overall, our findings suggest that a multicolumn approach provides a more accurate representation of the observed Balmer line emission, in agreement with results of numerical simulations.
format Preprint
id arxiv_https___arxiv_org_abs_2603_24807
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Understanding Balmer Decrements in T Tauri stars in terms of Multiflow Magnetospheric Accretion
Patiño, Naiara
Calvet, Nuria
Magris, Gladis
Micolta, Marbely
Thanathibodee, Thanawuth
Waters, Thomas K.
Colmenares, María José
Solar and Stellar Astrophysics
Magnetospheric accretion is the paradigm for accretion in Classical T-Tauri Stars (CTTS). However, the standard, one-flow magnetospheric accretion model fails to replicate important characteristics such as the observed Balmer decrements. We address this limitation by adopting a model with two axisymmetric magnetospheric accretion flows of different accretion rates and geometries. We calculate the fluxes of the hydrogen $H_α$, $H_β$, and $H_γ$ lines of each flow with the magnetospheric accretion model and use Bayesian statistics to fit the Balmer line fluxes of 139 CTTS in the Orion OB1b subassociation, and in the Upper Scorpius, Lupus and Chamaeleon I star-forming regions. We find that the Balmer decrements and line fluxes can be fitted by two distinct but coexisting flows: a compact, high accretion rate flow, close to the star and narrow (mean inner radius $R_i \sim 2.9 R_*$ and mean width $ΔR \sim 0.7 R_*$), covering a few percent of the emitting area, and a more spread out flow, thicker ($ΔR \sim 1.2 R_*$), and larger ($R_i \sim 3.7 R_*$), with lower accretion rate, encompassing the rest of the emitting area. The two-flow model can also reproduce the empirical correlation between the luminosity in $H_α$ and the accretion luminosity. Overall, our findings suggest that a multicolumn approach provides a more accurate representation of the observed Balmer line emission, in agreement with results of numerical simulations.
title Understanding Balmer Decrements in T Tauri stars in terms of Multiflow Magnetospheric Accretion
topic Solar and Stellar Astrophysics
url https://arxiv.org/abs/2603.24807