Fred Adams, Univ. Michigan Extreme Solar Systems II Jackson, Wyoming, September 2011.

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Presentation transcript:

Fred Adams, Univ. Michigan Extreme Solar Systems II Jackson, Wyoming, September 2011

Hot Jupiters can Evaporate HD209458b (Vidal-Madjar et al. 2003, 2004; Desert et al. 2008; Sing et al. 2008; Lecavelier des Etangs et al. 2008) HD189733b (Lecavelier des Etangs et al. 2010)

The Planetary System

Basic Regime of Operation

TWO COUPLED PROBLEMS LAUNCH of the outflow from planet PROPAGATION of the outflow in the joint environment of star and planet, including gravity, stellar wind, stellar magnetic field Matched asymptotics: Outer limit of the inner problem (launch of wind) provides the inner boundary condition for the outer problem (propagation of wind) This Work Focuses on Launch of the Wind

The Coordinate System

Magnetic Field Configuration OPEN FIELD LINES CLOSED FIELD LINES Magnetic field lines are lines of constant coordinate q. The coordinate p measures distance along field lines. Field lines are open near planetary pole and are closed near the equator. Fraction of open field lines:

Equations of Motion Steady-state flow along field-line direction: Fluid fields are functions of coordinate p only.

Two parameters specify the dimensionless problem

Solutions Sonic point Continuity eq. constant

Sonic Surface OUTFLOW DEAD ZONE

Fluid Field Solutions

Mass Outflow Rates

Physical Outflow Rate vs Flux

Column Density

Observational Implications

The Extreme Regime In systems where the stellar outflow and the stellar magnetic field are both sufficiently strong, the Planet can Gain Mass from the Star

The ZONE of EVAPORATION

Summary Planetary outflows magnetically controlled Outflow rates are moderately *lower* Outflow geometry markedly different: Open field lines from polar regions Closed field lines from equatorial regions In extreme regime with strong stellar outflow the planet could gain mass from the star Outflow rates sensitive to planetary mass: Reference: F. C. Adams, 2011, ApJ, 730, 27 see also: Trammell et al. (ApJ); Trammell Poster