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Transcript 
Proper Motion of the Andromeda Galaxy:
The Keystone of Local Group Dynamics
Jeremy Darling
Collaborators:
Andreas Brunthaler
Mark Reid
Kyle Willett
(CASA, University of Colorado)
Image Credit: Robert Gendler 2006
Proper Motion of the Andromeda Galaxy:
The Keystone of Local Group Dynamics
Is the Local Group bound?
What is its fate?
Does light trace mass?
Dark matter halos: mass, profile, size, shape
Image Credit: Robert Gendler 2006
Proper Motion of the Andromeda Galaxy:
The Keystone of Local Group Dynamics
- Astrometry Discovery Area
- Galactic Neighborhood Science Question:
What are the connections between dark and
luminous matter?
Image Credit: Robert Gendler 2006
The Woeful Inadequacy of
Extragalactic Maser Observations
Remember:
All masers seen in the Galaxy occur in other galaxies.
But, moving from kpc to Mpc distances,
Resolution down 1000-fold
Sensitivity down 106-fold
1 pc → 1 kpc
1 Jy → 1 µJy
Only a few species (water best)
Only a few 10’s of galaxies
The Woeful Inadequacy of
Extragalactic Maser Observations
Remember:
All masers seen in the Galaxy occur in other galaxies.
But, moving from kpc to Mpc distances,
Resolution down 1000-fold
Sensitivity down 106-fold
1 pc → 1 kpc
1 Jy → 1 µJy
Only a few species (water best)
Only a few 10’s of galaxies
We now have the
sensitivity to detect
Galactic analog masers
Darling, Brogan,
& Johnson
GBT survey
Darling, Brogan,
& Johnson
GBT survey
A Water Maser Survey of M31
Problems:
M31 is large!
Sensitivity to detect Galactic analogs
Low(er) star formation rate (8x less)
A Water Maser Survey of M31
Problems:
Solutions:
M31 is large! --Targeted survey of IR sources
Sensitivity to detect Galactic analogs -- GBT
Low(er) star formation rate (8x less) -- Large N
A Water Maser Survey of M31
Spitzer 24 micron (Gordon et al 2008)
Problems:
Solutions:
M31 is large! --Targeted survey of IR sources
Sensitivity to detect Galactic analogs -- GBT
Low(er) star formation rate (8x less) -- Large N
A Water Maser Survey of M31
N
E
Green Bank Survey:
- Select compact luminous 24 µm sources
(Spitzer; Gordon et al 2008)
- Sensitivity to detect Galactic analog masers in 5 minutes
200 Jy at 6 kpc (Galaxy) is 12 mJy at 780 kpc (M31)
- 206 sources, 32 hours
- Confirmation/refutation observations of a large fraction
A Water Maser Survey of M31
N
E
Green Bank Survey:
Methanol maser
Sjouwerman et al 2010
- Select compact luminous 24 µm sources
(Spitzer; Gordon et al 2008)
- Sensitivity to detect Galactic analog masers in 5 minutes
200 Jy at 6 kpc (Galaxy) is 12 mJy at 780 kpc (M31)
- 206 sources, 32 hours
- Confirmation/refutation observations of a large fraction
New Masers in the Andromeda Galaxy
N
E
Methanol maser
Sjouwerman et al 2010
CO (1-0) from Nieten et al (2006)
Spitzer 24 µm from Gordon et al (2008)
A Water Maser Survey of M31
N
E
Green Bank Survey Implications:
- 24 µm selection works, but is not predictive
- Can detect Galactic analog masers in Local Group
and beyond! (up to ~20 Mpc)
- Proper rotation, geometric distance possible to ~5 Mpc
- Proper motion possible to ~20 Mpc (depends on vpec)
Proper Motion ⇒ 3-D Velocity
~30 µarcsec/year (if 100 km/s)
N
E
- σµ ∝ t -3/2
- Expect ~6σ detection in ~3 years
** Arrows are schematic cartoons **
Rotation and Peculiar Velocities
N
E
Rotation curve from
Unwin (1983) and
Carignan et al (2006)
Proper Rotation ⇔ Geometric Distance
N
~15 µarcsec/year
E
~15 µarcsec/year
~70 µarcsec/year
D = VRot / µRot
- Distance error gets ~equal contributions from rotation
curve uncertainty and proper motion uncertainty (initially)
- Expect ~10% uncertainty (initially)
(c.f. Brunthaler et al work on M33)
Moving “Cluster” ⇒ Diverging Masers
N
~3 µarcsec/year divergence
E
µDiv = -Vr θ / D
- M31 gets larger on the sky as it approaches
- Largest maser separation is 1.8°
- Detectable in ~10 years?
- Cute, but useful?
Building a Comprehensive Maser
Network for Proper Motion Studies
N
E
24 µm identifies maser sites but is not predictive
Additional masers are likely!
Building a Comprehensive Maser
Network for Proper Motion Studies
N
GBT K-Band FPA
E
EVLA Primary Beam
24 mµ identifies maser sites but is not predictive
Additional masers are likely!
The Future
The Proper Motion of the Andromeda Galaxy
Keystone for Local Group kinematics, Dark Matter
Proper rotation yields distance
Moving cluster distance
Proper Motion of Other Galaxies
Galactic analog masers detectable to ~20 Mpc
Proper rotation, geometric distance possible to ~5 Mpc
Proper motion possible to ~20 Mpc
Bearing on Dark Matter
The End
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