Jérôme Bouvier (IPAG Grenoble, France)!

Sean Matt ! (U. Exeter, UK)!

Subu Mohanty (Imp. Col. London, UK)!

Aleks Scholz ! (U. St. Andrews, UK)!

Keivan Stassun ! (Vanderbilt U., USA)!

Claudio Zanni (Oss. Astro. di Torino, Italy)!

Protostars & Planets VI, Heidelberg!July 17, 2013!

Angular Momentum Evolution of Young Low-Mass Stars & Brown Dwarfs: Observations & Theory!

Stellar Rotation!

Importance of Stellar Rotation!

- Fundamental property: influences structure, mixing, evolution!

- Evolution of light elements (Be, Li)!

- Magnetic activity (UV, X-ray, spots, flares, mass loss)!

- Interaction between star and disk/planets!

- Studying rotational evolution complements knowledge:!!- stellar ages (gyrochronology)!!- history/future of activity!!- probes accretion/formation history, interior processes,

!mass loss rates!

Rotation & convection produces magnetic activity"magnetic fields, winds, spots, high energy radiation, …!

Rotation-activity relationship!

Log Rossby # = P / #conv!

Log

L x

/ L b

ol !

Wright et al. (2011)!

Non-saturated!

Saturated!

Magnetic properties depend on mass, rotation, & age.!

Magnetic field measurements (e.g., Johns-Krull 2007; Donati & Landstreet 2009; Gregory et al. 2010; Morin et al. 2011)!

Gregory et al. 2008!

V2129 Oph!

BP Tau!

Outline!

1. Observations of Stellar Rotation!

2. Physical Torque Mechanisms !

3. Models of Spin Evolution!

Observations of Stellar Rotation!

> 5000 new photometric periods since 2007 (in ~30 publications)!

Observations of Stellar Rotation!Solar Mass (0.9 – 1.1 Msun)!

Bouvier (2008)!

Then!

Gallet & Bouvier (2013)!

Now!

- Even sampling from 1 Myr ! 1 Gyr!

- Approaching statistically robust samples!

Age (Myr)!

Observations of Stellar Rotation!

Gallet & Bouvier (2013)!

Solar Mass (0.9 – 1.1 Msun)!

Power law spin down !(e.g., Skumanich 1972): !* " t-1/2 !Implies, torque " !*

3!Mag. activity: Non-saturated!

Pre-main-sequence:!- “Initial” distribution?!- distribution broadens to ZAMS!

Exponential spin down: !!* " exp(-t/#sd)!#sd ~ 100 Myr!Implies, torque " !*!Mag. activity: Saturated!

- Similar behavior down to the convective limit (~0.3 Msun)!

Observations of Stellar Rotation!Very Low Mass (<0.3 Msun)!

Gallet & Bouvier (2013)!

Solar mass!

Irwin et al. (2011)!

-  “Initial” distribution faster, & all stars spin-up toward ZAMS!- All stars on exponential spin-down, #sd ~ Gyrs!- Bifurcation? (Irwin et al. 2011; Morin et al. 2011; Gastine et al. 2013)!

Very low mass!

Irwin et al. (2011)!

~200 rotation periods!most in PMS!

- Mean ~2 days at PMS!(e.g., Cody & Hillenbrand 2010)!

- All rapid rotators at 1 Gyr!(e.g., Heinze et al. ’13; Girardin et al. ‘13; ! Gillon et al. ‘13)!

Not much angular momentum loss, #sd > 5 Gyr?!

Observations of Sub-Stellar Rotation!Brown Dwarfs (<0.08 Msun)!

Brown Dwarfs!

Outline!

1. Observations of Stellar Rotation!

2. Physical Torque Mechanisms !

3. Models of Spin Evolution!

Stellar Winds (non-accreting phase)!

Matt & Pudritz (2008), et al. (2012)!

New formula from simulations:!

Most models to date (e.g., Kawaler 1988) !!dJ/dt = Tw " B*2 $*!

Tw " Mw0.56 B*

0.87 $*!.!

Use “dynamo relationship:” B* R*2 " $*

a !Saturated: a = 0 ! exponential spin-down!Unsaturated: a = 1 ! Skumanich spin-down!

Stellar Winds, Key Developments!

!- Physical torque relates spin, B*, and mass loss rate (Matt et al. ‘08, ‘12)!

!- Mass loss rate determinations:!

! !- measurements (Wood et al. 2002, 2005)!

! !- steady wind theory (Cranmer & Saar 2011; Suzuki et al. 2013)!! !- CME Mdot inferred from flares (Aarnio et al. ‘12; Drake et al. ’12)!

!- Non-dipole B* models (Matt et al. ‘08, Cohen et al. ‘09, Vidotto et al. ‘10; Pinto et al. ’11)!

Accreting Phase!During PMS:!to counteract contraction &

accretion,!need ~106 % solar wind torque !

Gallet & Bouvier (2013)!

J conserved!

“Disk locking”!Can the star-disk interaction

provide these torques?!

Cieza & Baliber (2007)!

Accreting stars are (on average) slower rotators than non-accretors (maybe not for VLM stars)!

Accreting Phase!Accretion-Powered Stellar Winds!(Hartmann & Stauffer 1989; Matt & Pudritz 2005)!

Ghosh & Lamb (1978); Matt & Pudritz (2005)!

“propeller” regime?!D’Angelo & Spruit (2011); Romanova et al. (2009); Zanni & Ferreira (2013)!

Magnetic Star-Disk Connection!

Magnetospheric Ejections, Conical Winds!

Zanni & Ferreira (2013); Romanova et al. (2009)!

Disk “Viscosity” ! ! (Popham & Narayan 1991)!Gravitational Torques (Lin et al. 2011)!

Shu et al. (1994...);!Mohanty & Shu (2008)!

Obs. Support: Cauley et al. (2012)!

X-Wind!

Star-Disk Interaction, Key Developments!(still exploring mechanisms)!

!- APSW development (Meliani et al. ’06; Matt & Pudritz ‘07, ’08a,b; Cranmer ’08, ’09;

! ! ! Fendt ‘09; Zanni & Ferreira ’11; Sauty et al. ’11; Matt et al. ‘12) !

!- New mechanism, MEs (Zanni & Ferreira 2013)!

!- Effects of non-dipole fields:!

! !- X-wind (Mohanty & Shu 2008; Cauley et al. 2012; Ferreira & Casse 2013)!! !- disk truncation (Gregory et al. 2008)!! !- MHD simulations (Romanova et al. 2011; Long et al. 2007, 2008, 2009, 2011)!

!- Radiative transfer/high-res spectroscopy (Kurosawa et al., ‘06, ‘11, ‘12; !! ! ! !Bouvier et al. ‘07; Kwan et al. ’07; Fisher et al. ‘08; Alencar et al. ‘12)!

Gregory et al. ‘08!

BP Tau!

Outline!

1. Observations of Stellar Rotation!

2. Physical Torque Mechanisms !

3. Models of Spin Evolution!

Anatomy of (Most) Spin Evolution Models!Goal: get $*(t)!

(1)  1D evolution model (structure, moment of inertia)!!+ solve dJ/dt equation!

(2) External torques: !!Stellar winds: Kawaler88 + dynamo + “saturation”!!accretion-phase: not treated physically ! “disk locking”!

(3) Internal transport of angular momentum:!!solid body or 2-zone with “decoupling”!!some solve transport in radiative zone!

Spin Evolution Models, Highlights!

Gallet & Bouvier (2013)!

Solar mass stars!

- Realistic Tw (Matt et al. 2012) and mass loss rates (Cranmer & Saar 2011)!

- Slow rotators less “coupled” (#c-e ~ 30 Myr versus 12 Myr)!

Spin Evolution Models, Highlights!

Irwin et al. (2011)!

- Internal transport: circulations, instabilities, gravity waves, B-fields! (e.g., Decressin et al. 2009; Denissenkov et al. 2010; Turck-Chièze et al. 2010; Strugarek et al.! 2011; Marques et al. 2013; Charbonnel et al. 2013) (Asteroseismology: e.g., Beck et al. 2011)!

APSW; B* = 2 kG!

Matt et al. (2012)!

-  Accretion phase! spin evolution ! (Matt et al. 2010, 2012)!

- Mass dependence of spin-down (Reiners & Mohanty 2012) !

Tw " M*-2/3 R*

16/3 (?) !

Reiners & Mohanty (2012)!

B* R*2 " $*

a!

Open Q’s, Near Future Prospects!-  What gives rise to “initial” spin rates and distributions?!

-  What is most important mechanism(s) for PMS ang. mom. loss?!

-  Explanation for range of spin rates at given mass/age (formation conditions, !accretion history, coupling timescales, dynamo modes/bistability…)?!

-  Will see large increase in observed magnetic field maps; need more models !considering realistic fields!

-  Are magnetic fields strong enough for existing models to work!

- Improved mass loss rates (measurements & models, accreting & non-accreting !phases)!

-  Improved physics in spin evolution models (accretion phase, internal transport, !better torque models…)!

- More spin rate measurements, especially VLM field stars, asteroseismology!

- Improved/cleaner sampling in PMS & better ages/masses/acc. rates, etc.!

“And in the end, it’s only round and round and round...” - Pink Floyd, DSOTM !