what have we learned from eclipsing binaries in the orion nebula?
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What have we learned from Eclipsing Binaries in the Orion Nebula?. Keivan Guadalupe Stassun Vanderbilt University. Dynamical Masses of PMS Stars circa 2013. N=33 M < 2 M sun. Single stars Circumstellar disk “rotation curve” Binary stars Astrometric Eclipsing. - PowerPoint PPT PresentationTRANSCRIPT
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What have we learned from Eclipsing Binaries in the Orion Nebula?
Keivan Guadalupe StassunVanderbilt University
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Dynamical Masses of PMS Stars
circa 2013N=33
M < 2 Msun
Single stars Circumstellar disk
“rotation curve”
Binary stars Astrometric Eclipsing
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Accurate masses and radii: Eclipsing binaries
Stassun et al. (2004)
V1174 Ori M1 = 1.01 ± 0.015 Msun
M2 = 0.73 ± 0.008 Msun
R1 = 1.34 ± 0.015 Rsun
R2 = 1.07 ± 0.011 Rsun
T1 = 4470 ± 120 K
T2 = 3615 ± 10 K
log g1 = 4.19 ± 0.01
log g2 = 4.25 ± 0.01Masses, Radii, and Teff ratio measured very accurately.
Luminosities are distance independent.
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Comparison of dynamical masses to theoretical models in HR diagram
Above 1 Msun:
• Good agreement: Mean difference 10%, scatter ~10%.
Below 1 Msun:
• Poorer agreement: Differences as large as ~100%, large scatter.
Best overall agreement: Siess et al (2000), and Palla & Stahler (1999):
• Overall consistency to ~5%, though with scatter of ~25%.
Updated from Hillenbrand & White (2004)
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Case Study: Par 1802A pair of dissimilar ‘identical twins’
Alicia Aarnio (Michigan)
Yilen Gómez (Vanderbilt)
Bob Mathieu (Wisconsin)
Phillip Cargile (Vanderbilt)
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Par 1802: Non-coevality?
T1/T2 = 1.092 ± 0.002
R1 = 1.82 ± 0.05 Rsun
R2 = 1.69 ± 0.05 Rsun
L1/L2 = 1.62 ± 0.03
M1 = 0.39 ± 0.02 Msun
M2 = 0.38 ± 0.02 Msun
q = 0.98 ± 0.01
Stassun et al. (Nature, 2008)
1. In protobinary phase, original secondary preferentially accreted mass.
2. Secondary ended accretion phase later. 3. Apparent age difference because different
t=0 due to different accretion histories. e.g. Simon & Stobie (2009), Clarke (2007), Bate
(2004)
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Par 1802: Tidal heating by third body?
T1/T2 = 1.092 ± 0.002
R1 = 1.82 ± 0.05 Rsun
R2 = 1.69 ± 0.05 Rsun
L1/L2 = 1.62 ± 0.03
M1 = 0.39 ± 0.02 Msun
M2 = 0.38 ± 0.02 Msun
q = 0.98 ± 0.01
Stassun et al. (Nature, 2008)
Gomez et al. (ApJ, 2012)
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Triples among known PMS eclipsing binaries
•7 triples : 40 doubles = 18% (MS all; Duquennoy & Mayor 1991)•2 triples : 19 doubles = 11% (PMS all; Ghez et al. 1997)•8 triples : 13 doubles = 61% (PMS SBs; Guenther et al. 2007)•8 triples : 6 doubles = 133% (PMS EBs; Stassun & Hebb in prep.)
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Case Study: 2M0535-05The First Brown-Dwarf Eclipsing Binary
Bob Mathieu (Wisconsin)
Jeff Valenti (STScI)
Yilen Gómez (Vanderbilt)
Matthew Richardson (Vanderbilt)
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M1 = 60 ± 3 MJup
M2 = 39 ± 2 MJup
R1 = 0.67 ± 0.03 Rsun
R2 = 0.51 ± 0.03 Rsun
Temperature reversal
Stassun et al. (Nature, 2006)
Stassun et al. (ApJ, 2007)
Mohanty et al. (ApJ, 2009)
T2/T1 = 1.051T2/T1 = 1.051
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Primary brown dwarf ~10 more magnetically active than secondary.
Reiners et al. (ApJ, 2007)
Gómez et al. (ApJ, 2009)
P1 = 3.293 ± 0.001 days
P2 = 14.10 ± 0.05 days
Primary BD has strong surface activity
B ~ 4 kG
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Active, primary brown dwarf shifted to cooler Teff, apparently lower mass
Mohanty et al. (ApJ, 2009)
Stassun et al. (ApJ, 2012)
1 Myr
T2/T1 = 1.051±0.004
T2/T1 = 1.051±0.004
2M0535-05: Brown Dwarf Eclipsing
Binary in Orion
Stassun et al. (Nature 2006,
ApJ 2007)
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Inflated R and Suppressed Teff in Active Low-mass Eclipsing Binaries
Lopez-Morales (ApJ, 2007)Stassun et al. (ApJ, 2012)
Sample: •11 stars in 7 EB systems•Direct, accurate masses, radii, and Teff•X-ray luminosity measurements•LX to LH relation of Scholz et al. (2007)
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Inflated R and Suppressed Teff in Active Field M-dwarfs
Morales et al. (AJ, 2008)
Stassun et al. (ApJ, 2012)Sample:
•PMSU catalog•700 M-dwarfs with distances, spectral types, K mags, H measures•Radii via Stefan-Boltzmann law•Masses via BCAH98 tracks
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An Empirical Relation Linking R Inflation and Teff Suppression
to HEmission
Stassun et al. (ApJ, 2012)
Applicability: •M < 0.8 Msun•-4.6 < log LH/Lbol < -3.3
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Primary brown dwarf in 2M0535-05 effectively corrected in HR diagram
1 Myr
Stassun et al. (ApJ, 2012)
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New generation PMS models: Incorporating effects of magnetic activity
New models incorporating magnetic field effects on stellar structure and evolution
can successfully explain R inflation(Feiden & Chaboyer, ApJ 2012)
New models show promise when compared to PMS EBs: 2-3x better agreement with dynamical masses
(Stassun, Feiden, & Torres, in prep.)
Torres et al. (ApJ, 2013)
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Summary Large uncertainties remain in theoretical stellar evolution models.
Some models perform better than others in HR diagram, but… PMS is complex: activity effects, accretion histories, third bodies
Magnetic activity alters Teff and R of low-mass stars and brown dwarfs (but Lbol appears to be ok).
Beware mass and age estimates for active low-mass field objects: Teff or color based mass estimates can be too low by factor of ~2.
Empirical relations useful for correcting Teff, R, and M estimates via H.
Apparent non-coevality of ~50% possible in low-mass binaries at ~1 Myr. Accretion history of protobinaries may be important for setting final masses. Tidal heating history and role of third bodies may be important for observed
luminosities.
New PMS models incorporating magnetic effects show promise.
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Fabienne Bastien (Vanderbilt)
Josh Pepper (Lehigh)
Gibor Basri (Berkeley)
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Measuring stellar structure from “flicker” and “crackle”
Bastien et al. (2013, Nature)
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Measuring stellar structure from “flicker” and “crackle”
Bastien et al. (2013, Nature)
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http://filtergraph.vanderbilt.edu/