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High Contrast AO Imaging at the MMT with ARIES SDI
Laird Close, Beth Biller, Eric Nielsen
Don McCarthy
& MMT AO Group
(Steward Obs)
High Contrast AO Imaging at the MMT with AO
MMT has world’s first
(and so far only)
adaptive secondary
Can produce very high
strehl images in the
thermal IR (see talks by
Beth Biller, Wilson Liu
& Ari Heinze
tomorrow).
And ~20% Strehls in the
NIR (subject of this
talk)
First NIR AO science from the adaptive secondary:
TheTheta Ori B mini-cluster
Close et al. 2003
Above we see images of the theta 1 Ori B "mini-cluster" made with the
Indigo commercial IR video camera at H band. Significant orbital motion
was observed of B3 orbiting B2 when we compared this image to those
of previous years. Moreover, it appears that B2/B3 is bound to B1/B5
since nor orbital motion was observed. In addition, the very low mass
(~0.2 Mo) star B4 appears to be a common proper motion member of
the B "mini-cluster". Since our orbital analysis shows B4 is in a very
unstable position this "mini-cluster" may, in time, eject B4. This has been
recently hypothesized to an important method of producing low mass
stars and brown dwarfs through dynamical ejection processes.
Here we see that B4 appears like a common motion pair
(4+/-15 km/s of relative motion) with the B group.
Simulations suggest that the faintest component (B4) will
be ejected from this “mini-cluster” in less than 100 orbits!
Close et al. 2003
High Contrast AO Imaging at the MMT with ARIES
ARIES is the
MMT’s NIR
AO imager
PI Don
McCarthy
The Simultaneous Differential
Imaging (SDI) Technique
• Pioneered by Marois et al.
2000.
• Sample inside and outside of
the strong CH4 (methane
absorption) bandhead at 1.62
mm in extrasolar giant
planets (T < 1200 K)
• Subtract out star and
speckles between filters –
any CH4 rich companion
should remain.
Nielsen et al. 2004 Biller et al. 2006
The SDI Instruments
Double Wollaston and Quad
Filter– Calcite Prisms split beam
into 4 identical beams while
minimizing non common path
error (Close et al. 2004).
• Installed in the ARIES camera
at the MMT AO system by Don
McCarthy and Laird Close (and
in the CONICA camera inside
the VLT NACO AO system by
Laird Close and Rainer Lenzen).
• NACO and ARIES SDI fully
commissioned.
Proof of Concept –
SDI Discovery of the Methane Rich Brown
Dwarf SCR 1845B – Just 3.8 pc from Sun!
M8.5 + T5.5
Biller et al. 2006
ARIES SDI Images of the tight brown dwarf binary GL 569B
High Contrast AO Imaging at the MMT with ARIES SDI
GL 569B is a critical low mass, young, evolutionary track
calibrator. We can determine from our SDI images that there
are no T-dwarf (methane rich) companions to GL 569 A or B
Smooth MMTAO SDI AO PSF
HD128311 K0 500Myr 2.2 & 3.2 Mj msin(i)
Smooth MMTAO ARIES AO PSF of HD128311
after SDI subtraction
High Contrast AO Imaging at the MMT with ARIES SDI
Biller et al.
2006
ARIES MMTAO SDI
Tentative Exoplanet candidate
Biller et al. 2006
The SDI Young Stars Survey
Survey object selection criterion:
• Age: less than 300 Myr, preferably less than
100 Myr.
• Distance: less than 50 pc – and the closer, the
better.
• Spectral Type: focus on young solar analogues,
but also pay attention to low mass stars.
• Datasets acquired for ~50 objects (at MMT
and VLT with SDI).
SDI targets observed
Biller et al. 2006
Achievable Contrasts
K1V primary, 15 pc, ~70 Myr, V=6.88
Biller et al. 2006
So what does this all mean?
• For a ~50 object survey, we
expect to detect ~4 planets
(from Monte Carlo simulations using
realistic scaling laws (Marcy et al.
2003) and models (Burrows et al.
2003))
• Even if we get a null result
(no planets), we will be
able to place strong
constraints (> 2s) on the
frequency and semimajor
axis distribution of young
massive extrasolar planets
>5 AU from their
primaries.
Nielsen et al. 2006