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WITNESSING PLANET FORMATION WITH ALMA AND THE ELTs

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WITNESSING PLANET FORMATION WITH ALMA AND THE ELTs ABSTRACT: Over the last 15 years, astronomers have discovered over 400 mature exoplanets in the solar neighborhood. – PowerPoint PPT presentation

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Title: WITNESSING PLANET FORMATION WITH ALMA AND THE ELTs


1
WITNESSING PLANET FORMATION WITH ALMA AND THE
ELTs
ABSTRACT Over the last 15 years, astronomers
have discovered over 400 mature exoplanets in the
solar neighborhood. However, the precise
mechanisms through which planets are formed still
remain largely unknown. The situation is
particularly troubling for giant planets, for
which two fundamentally dissimilar formation
models exists, namely core accretion (Lissauer
1993) and gravitational instability (Boss 2000).
Fortunately, and thanks to the unprecedented
sensitivity and resolution of the Atacama Large
Millimeter Array (ALMA) and the Extremely Large
Telescopes (ELTs), we are now on the verge of
being able to observe ongoing planet formation in
primordial circumstellar disks. Here we review
the capabilities of these new facilities, which
will most likely revolutionize our current
understanding of planet formation.
Lucas Cieza, IfA/U. of Hawaii
The targets observing systems that are actively
forming planets is the most promising path to
progress in understanding the planet formation
process. The so called transition objects (PMS
stars with optically thin inner disks and
optically thick outer disks) are currently the
most likely sites of ongoing planet-formation. It
is increasingly clear that many of these systems
have recently formed giant planets still embedded
within the primordial disk (Espaillat et al.
2008 Cieza et al. 2010). These systems, such as
DM Tau, GM Aur, LkCa 15, and OPH TRAN 32 (see
Fig. 1), are prime targets for detailed followup
observations with ALMA and the ELTs.
TMT
E-ELT
GMT
Table 1. The physical resolution of the TMT as a
function of wavelength and distance. The ELTs
will be able to detect planets with separaration
as small as 5 AU at the distance of the
Ophiuchus and Taurus SFRs (d 125-140 pc) and as
small as 2 pc at the distance of the TW Hydra
association (d 60 pc). Table taken from the TMT
detailed science case 2007.
Fig 4. Brightness ratio between the planet and
the host star as a function of angular separation
for different types of exoplanets. The detection
limits of the Planet Formation Instrument planed
for the TMT are shown as a red curve. The ELTs
will be able to directly detect giant planets in
nearby star-forming regions (SFRs) such as Taurus
(d 140 pc). Figure taken from the TMT Detailed
Science Case 2007.
Table 2. Limiting distances as a function of
total disk mass detectable with TMT-MIRES
observations of H2. Disk masses as small as 10-5
Msun will be detectable up to 450 pc, the
distance of the Orion Nebula Cluster. Table taken
from the TMT detailed science case 2007.
  • Planet formation science enabled by the ELTs
  • Direct detection of self-luminous giant
    planets in nearby star-forming regions (d 125
    -150 pc) using extreme Adaptive Optics
    instruments such as the Planet Formation
    Instrument (PFI) on the TMT and the Exo-Planet
    Imaging Camera and Spectrograph (EPICS) on the
    E-ELT (see Figure 4).
  • Probing the dissipation timescale of the bulk
    of the gas in the planet formation regions of
    disks by observing tracers such as H2(S2) at 12.4
    ?m and H2 (S1) at 17 ?m (see Table 2) using
    high-resolution mid-IR spectrographs such as
    MIRES on the TMT and METIS on the E-ELT. This is
    crucial to distinguish between competing planet
    formation theories (e.g., core accretion and
    gravitational instability).
  • Study the distribution and dynamics of
    pre-biotic molecules, such as H2O, CH4, HCN, and
    C2H2 in the planet-forming regions of the disk
    (0.5 - 20 AU) using high-resolution near and
    mid-IR spectroscopy. These studies with the ELTs
    will complement similar chemistry studies of the
    outer disk that can be performed with ALMA.
  • Planet formation science enabled by ALMA
  • High resolution (few AU scale) imaging of
    transition disks to constrain their structure and
    search for gaps, spiral density waves, and other
    indications of dynamical interactions with
    forming giant planets.
  • Direct detection of forming giant planets to
    directly address the question of how and when
    giant planets form in circumstellar disks (see
    Figure 3).
  • CO observations to investigate the dynamics of
    the gas and establish how turbulent circumstellar
    disks really are and whether they are conducive
    to gravitational instability.
  • High-resolution, multi-wavelength continuous
    observations to establish the grain size
    distribution as a function of radius, which has
    important implications for grain growth and
    radial mixing.
  • Survey of binary systems with IR excess to
    constrain the distribution of circumstellar
    material and establish which type of binary
    systems are conducive to planet formation.
  • References
  • Boss, A. 2000, ApJL, 536, 101
  • Cieza, L. et al. 2010, ApJ, 712, 925
  • Espaillat, C. et al. 2008, ApJL, 682, 125,
  • Lissauer J. 1993, ARAA, 31, 129
  • Wolf, S. 2008, ApSS, 313. 109
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