Bibcode
DOI
Zapatero Osorio, M. R.; Caballero, J. A.; Béjar, V. J. S.
Referencia bibliográfica
The Astrophysical Journal, Volume 621, Issue 1, pp. 445-460.
Fecha de publicación:
3
2005
Revista
Número de citas
55
Número de citas referidas
52
Descripción
We report on the linear polarimetric observations in the Johnson I-band
filter of 44 ultracool dwarfs with spectral types between M6 and L7.5,
corresponding to effective temperatures in the range 2800-1400 K, and
one M4.5-type star. Based on our measurements of polarization (P) and
their associated error bars (σP), 11 (10 L and 1 M)
dwarfs appear to have significant linear polarization
(P/σP>=3). For these, the polarization degrees we
have measured are in the interval P=0.2%-2.5%. Because of the typical
average uncertainty of our data, we can easily confirm polarization of
ultracool dwarfs that show degree of linear polarization greater than
0.4%. We have compared the two populations in our sample, the M and L
type dwarfs, and have found evidence for a larger frequency of high
I-band polarization in the coolest objects, supporting the presence of
significant amounts of dust in L-type atmospheres. The probable
mechanism polarizing the far-red optical photons of ultracool dwarfs is
related to the presence of heterogeneous dust clouds nonuniformly
distributed across the visible photospheres and the asymmetric shape of
the objects (rapid rotations impose deviations from sphericity). In some
young ultracool dwarfs, surrounding dusty disks (or shells) may also
yield polarization. For polarimetric detections, a trend for slightly
larger polarization from L0 to L6.5 may be present in our data,
suggesting changes in the distribution of the grain properties and in
the vertical height of the cloud layer. Faster rotations and important
differences in metallicity and age within our sample could also account
for this trend. One of the targets is the peculiar brown dwarf 2MASS
J22443167+2043433 (L6.5), for which we have determined the largest
I-band polarization degree in our study. We discuss that the origin of
such large polarization may lie in a surrounding dusty disk (or shell)
and/or rather large photospheric dust grains. Two of the likely
polarized dwarfs (CFHT-BD-Tau 4, a very young, M7-type brown dwarf of
the Taurus star-forming region, and 2MASS J00361617+1821104, an L3.5
field dwarf) were also observed in the Johnson R-band filter, allowing
us to discuss qualitatively the size of the grains responsible for the
polarization. Our data support the presence of a circum(sub)stellar disk
around the young accreting brown dwarf CFHT-BD-Tau 4. The higher degree
of polarization in the R band than in the I band indicates that the
grain growth lies in the submicron regime in the visible photosphere of
2MASS J00361617+1821104 (effective temperature of about 1900 K). Our
polarimetric data does not obviously correlate with activity (Hα
and radio emission) or projected rotational velocity. Three polarized
early- to mid-L dwarfs have been photometrically monitored in the I
band, displaying light curves with amplitudes below 10 mmag.