Bibcode
Guieu, S.; Dougados, C.; Monin, J.-L.; Magnier, E.; Martín, E. L.
Referencia bibliográfica
Astronomy and Astrophysics, Volume 446, Issue 2, February I 2006, pp.485-500
Fecha de publicación:
2
2006
Revista
Número de citas
97
Número de citas referidas
91
Descripción
Recent studies of the substellar population in the Taurus cloud have
revealed a deficit of brown dwarfs compared to the Trapezium cluster
population. However, these works have concentrated on the highest
stellar density regions of the Taurus cloud. We have performed a large
scale optical survey of this region, covering a total area of ≃28
deg^2, and encompassing the densest parts of the cloud as well as their
surroundings, down to a mass detection limit of 15 M_J. We present the
optical spectroscopic follow-up observations of 97 photometrically
selected potential new low-mass Taurus members, of which 27 are strong
late-M spectral type (SpT ≥ M4V) candidates. Our spectroscopic survey
is 87% complete down to i'=20 for spectral types later than M4V, which
corresponds to a mass completeness limit of 30 MJ for ages
≤10 Myr and Av ≤ 4. We derive spectral types, visual absorption
and luminosity class estimates and discuss our criteria to assess Taurus
membership. These observations reveal 5 new VLM Taurus members and 12
new BDs. Two of the new VLM sources and four of the new substellar
members exhibit accretion/outflow signatures similar to higher mass
classical T Tauri stars. From levels of Hα emission we derive a
fraction of accreting sources of 42% in the substellar Taurus
population. Combining our observations with previously published
results, we derive an updated substellar to stellar ratio in Taurus of
R_ss=0.23 ± 0.05. This ratio now appears consistent with the
value previously derived in the Trapezium cluster under similar
assumptions of 0.26 ± 0.04. We find indications that the relative
numbers of BDs with respect to stars is decreased by a factor 2 in the
central regions of the aggregates with respect to the more distributed
population. Our findings are best explained in the context of the
embryo-ejection model where brown dwarfs originate from dynamical
interactions in small N unstable multiple systems.