84 research outputs found
Mass Estimates of a Giant Planet in a Protoplanetary Disk from the Gap Structures
A giant planet embedded in a protoplanetary disk forms a gap. An analytic
relationship among the gap depth, planet mass , disk aspect ratio ,
and viscosity has been found recently, and the gap depth can be
written in terms of a single parameter . We discuss how observed gap features can be used to constrain the
disk and/or planet parameters based on the analytic formula for the gap depth.
The constraint on the disk aspect ratio is critical in determining the planet
mass so the combination of the observations of the temperature and the image
can provide a constraint on the planet mass. We apply the formula for the gap
depth to observations of HL~Tau and HD~169142. In the case of HL~Tau, we
propose that a planet with is responsible for the observed gap at
~AU from the central star based on the estimate that the gap depth is
. In the case of HD~169142, the planet mass that causes the gap
structure recently found by VLA is . We also argue that the
spiral structure, if observed, can be used to estimate the lower limit of the
disk aspect ratio and the planet mass.Comment: 16 pages, 5 figures, accepted for publication in The Astrophysical
Journal Letter
High Angular Resolution, Sensitive CS J=2-1 and J=3-2 Imaging of the Protostar L1551 NE: Evidence for Outflow-Triggered Star Formation ?
High angular resolution and sensitive aperture synthesis observations of CS
() and CS () emissions toward L1551 NE, the second brightest
protostar in the Taurus Molecular Cloud, made with the Nobeyama Millimeter
Array are presented. L1551 NE is categorized as a class 0 object deeply
embedded in the red-shifted outflow lobe of L1551 IRS 5. Previous studies of
the L1551 NE region in CS emission revealed the presence of shell-like
components open toward L1551 IRS 5, which seem to trace low-velocity shocks in
the swept-up shell driven by the outflow from L1551 IRS 5. In this study,
significant CS emission around L1551 NE was detected at the eastern tip of the
swept-up shell from = 5.3 km s to 10.1 km s, and
the total mass of the dense gas is estimated to be 0.18 0.02 .
Additionally, the following new structures were successfully revealed: a
compact disklike component with a size of 1000 AU just at L1551 NE,
an arc-shaped structure around L1551 NE, open toward L1551 NE, with a size of
AU, i.e., a bow shock, and a distinct velocity gradient of the
dense gas, i.e., deceleration along the outflow axis of L1551 IRS 5. These
features suggest that the CS emission traces the post-shocked region where the
dense gas associated with L1551 NE and the swept-up shell of the outflow from
L1551 IRS 5 interact. Since the age of L1551 NE is comparable to the timescale
of the interaction, it is plausible that the formation of L1551 NE was induced
by the outflow impact. The compact structure of L1551 NE with a tiny envelope
was also revealed, suggesting that the outer envelope of L1551 NE has been
blown off by the outflow from L1551 IRS 5.Comment: 29 pages, 12 figures, Accepted for Publication in the Astrophysical
Journa
Interferometric Observations of Formaldehyde in the Protoplanetary Disk around LkCa15
Emission from the line of HCO has been detected and
marginally resolved toward LkCa15 by the Nobeyama Millimeter Array. The column
density of HCO is higher than that observed in DM Tau and than predicted by
theoretical models of disk chemistry; also the line-intensity profile is less
centrally peaked than that for CO. A similar behavior is observed in other
organic gaseous molecules in the LkCa 15 disk.Comment: 5 pages, 4 figures. accepted to PASJ (Publication of Astronomical
Society of Japan
- …