CSFD 2006, Toronto, 18 June 2006 Numerical simulation of supersonic escape from planetary atmospheres Hans De Sterck, Paul Ullrich, Scott Rostrup Department.

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CSFD 2006, Toronto, 18 June 2006 Numerical simulation of supersonic escape from planetary atmospheres Hans De Sterck, Paul Ullrich, Scott Rostrup Department of Applied Mathematics, University of Waterloo Feng Tian Department of Astrophysical and Planetary Sciences, University of Colorado at Boulder, USA

CSFD 2006, Toronto, 18 June 2006 Outline 1.Supersonic gas escape from extrasolar planets 2.1D numerical models 3.2D numerical models 4.3D numerical models 5.Supersonic gas escape from Early Earth

CSFD 2006, Toronto, 18 June 2006 (1) Supersonic gas escape from extrasolar planets 173 extrasolar planets known, as of June multiple planet systems many exoplanets are gas giants (“hot Jupiters”) many orbit very close to star (~0.05 AU) hypothesis: strong irradiation leads to supersonic hydrogen escape

CSFD 2006, Toronto, 18 June 2006 similar to solar wind

CSFD 2006, Toronto, 18 June 2006 example: HD (Vidal-Madjar 2003) 0.67 Jupiter masses, 0.05 AU, transiting hydrogen atmosphere and escape observed question: what is the mass loss rate? long-time stability of the planet?

CSFD 2006, Toronto, 18 June 2006 (2) 1D numerical models compressible gas dynamics (Euler equations)

CSFD 2006, Toronto, 18 June 2006 transonic radial outflow solution

CSFD 2006, Toronto, 18 June 2006 numerical method time-marching to steady state use standard CFD methods: finite volume method with Riemann solver very slow convergence to steady state!

CSFD 2006, Toronto, 18 June 2006 results for 1D exoplanet simulations HD209458b:  lower boundary conditions n= cm -3 and T=750K  extent of atmosphere, outflow velocity, and mass flux consistent with observations (Vidal-Madjar 2003)  1% mass loss in 12 billion years  HD209458b is stable A planet with 0.5 Uranus 0.4AU AND under 10X solar EUV radiation has 10% mass loss in ~850 million years (preliminary results)  Is Mercury the remnant of a giant planet? Tian, Toon, Pavlov, and De Sterck, Astrophysical Journal 621, , 2005

CSFD 2006, Toronto, 18 June 2006 (3) 2D numerical models (Scott Rostrup) Euler equations in multiple dimensions

CSFD 2006, Toronto, 18 June D Simulations assume rotational symmetry about the y axis  allows for non-uniform heating

CSFD 2006, Toronto, 18 June 2006 non-uniform heating Density Temperature Mach Number ● heated by a thin layer in the northern hemisphere ● outflow mass flux similar to 1D case ● 1D gives reasonable approximation

CSFD 2006, Toronto, 18 June 2006 ongoing work: include stellar wind

CSFD 2006, Toronto, 18 June 2006 compare with artist’s impression...

CSFD 2006, Toronto, 18 June 2006 (4) 3D numerical models (Paul Ullrich) we want to include effects of planetary rotation topology: grid between two concentric spheres if one wants uniform point density in all directions, one is naturally led to the use of unstructured grids (avoid the polar problem)

CSFD 2006, Toronto, 18 June 2006 unstructured triangular grid on inner boundary

CSFD 2006, Toronto, 18 June 2006 build stacks of triangular prisms out from the inner boundary

CSFD 2006, Toronto, 18 June 2006 preliminary 3D finite volume results

CSFD 2006, Toronto, 18 June 2006 (5) Supersonic gas escape from Early Earth there is no supersonic hydrodynamic escape from present-day Earth exo-base temperature is high: collisional, thermal escape dominates

CSFD 2006, Toronto, 18 June 2006 Supersonic gas escape from Early Earth hypothesis: when the Earth was young, the exo-base temperature may have been low, and supersonic hydrodynamic escape may have been ongoing test of hypothesis: do 1D simulation, find exobase temperature, and outflow flux  our simulations confirm cold exobase and hydrodynamic escape with small mass flux this finding also has implications for hydrogen content in Early Earth atmosphere!

CSFD 2006, Toronto, 18 June 2006 primordial soup as the origin of life Stanley Miller (1953): formation of prebiotic molecules in a CH4-NH3 rich environment with electric discharge  Problem: CH4-NH3 atmosphere unlikely later experiments show that prebiotic molecules can be formed efficiently in a hydrogen-rich environment. alternative sources of organics: hydrothermal system, extraterrestrial delivery

CSFD 2006, Toronto, 18 June 2006 hydrogen content in Early Earth atmosphere hydrogen content: balance between volcanic outgassing and escape from atmosphere existing theories claim that hydrogen content was very low, as hydrogen escape rates through thermal processes were assumed very large formation of prebiotic molecules in a hydrogen-rich atmosphere was thus discarded as a theory

CSFD 2006, Toronto, 18 June 2006 hydrogen content in Early Earth atmosphere our results: hydrogen escape was probably hydrodynamic, and escape rates were low our results: hydrogen concentration in the atmosphere of Early Earth could have been as high as 30% formation of prebiotic molecules in early Earth’s atmosphere could have been efficient  primordial soup on early Earth is possible no need for hydrothermal vents, extraterrestrial delivery Tian, Toon, Pavlov, and De Sterck, Science 308, , 2005