J. R. Spreiter scite author profile

-A magnetohydrodynamic model f o r the inceraction o f t h e s o l a r wind and t h e geomagnetic f i e l d i s described, t h e degree t o which t h e I n t h e hydromagnetic model, the magnetosphere boundary and d i s t a n t t a i l a r e represented by t a n g e n t i a l and contact d i s c o n t i n u i t i e s , and the bow wave by a fast hydromagnetic shock wave. The connectivity of i n t e r p l a ne t a r y and geomagnetic f i e l d s , and t h e asymptotic d i r e c t i o n s of t h e wake and shock waves at g r e a t d i s t a r c e s f r o n t h e e a r t h a r e discussed i n terms of p r o p e r t i e s of these d i s c o n t i n u i t i e s . Detailed numerical r e s u l t s f o r t h e location of the bow wave, and t h e density, velocity, and temperature of t h e flow i n t h e region between t h e bow wave and t h e magnetosphere are presented f o r Mach numbers 5, 8, and 12 f o r 7 = 5/3 and 2. The calcul a t e d position of t h e bow wave i s shown t o be i n good accordance with t h a t observed i n shadowgraph photographs of supersonic flow p a s t a model magnetosphere i n the Ames Supersonic Free-Flight Wind Tunnel. Results Ia r e a l s o presented that i l l u s t r a t e t h e d i s t o r t i o n of t h e i n t e r p l a n e t a r y magnetic f i e l d i n t h e region between t h e bow and t h e magnetosphere f o r cases i n which t h e magnetic f i e l d i n t h e incident stream i s i n c l ' ed at 45' and 90' t o t h e free-stream direction.

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Solar wind flow about the outer planets: Gas dynamic modeling of the Jupiter and Saturn bow shocks

Slavin¹,

Smith²,

Spreiter³

et al. 1985

J. Geophys. Res.

124

206

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Pioneer 10 and 11 and Voyager 1 and 2 observations are used to study global aspects of the solar wind interaction with Jupiter and Saturn. Solar wind measurements before and after the encounters are used to determine average upstream flow parameters at 5 and 9 AU. Bow shock and magnetopause position are found to vary as the fourth root of dynamic pressure at Jupiter and the sixth root at Saturn. The average distances to the nose of the magnetopause based upon the Pioneer and Voyager boundary crossings for Jupiter and Saturn are 68 RJ and 19 RS, respectively, after correction for varying solar wind pressure. In shape, the Jovian bow shock and magnetopause surfaces are similar to their terrestrial counterparts, but the width of the magnetosheath is 45% less than predicted by axisymmetric gas dynamic theory. This result is interpreted as evidence for strong polar flattening of the Jovian magnetosphere. The Saturnian magnetopause and bow shock boundaries are significantly more flared than at the earth with a subsolar magnetosheath that is 20% thinner than predicted by gas dynamic theory. On the basis of these results it is suggested that Saturn is intermediate between the earth and Jupiter in terms of polar flattening, with the unusual flaring of the Saturn magnetopause being due to the low ratio of static to dynamic pressure in the distant heliosphere.

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Patterns of potential magnetic field merging sites on the dayside magnetopause

Luhmann¹,

Walker²,

Russell³

et al. 1984

J. Geophys. Res.

240

197

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Models of the magnetospheric and magnetosheath magnetic fields are used to determine the relative orientations of these fields at the dayside magnetopause in order to locate potential merging sites. Areas on the magnetopause with different fractional antiparallel components are displayed by contour diagrams for a variety of interplanetary field orientations. For interplanetary fields oriented perpendicular to the solar wind velocity the areas of nearly antiparallel field agree with those obtained by Crooker using simplified representations for the magnetic field geometry. Here, the application of more realistic models gives the locations of areas where any antiparallel component occurs. Potential merging sites for interplanetary fields with radial components are also illustrated. The results suggest that the topology of the magnetosheath and magnetospheric fields provides antiparallel components over a substantial fraction of the magnetopause for most interplanetary field orientations.

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A new predictive model for determining solar wind‐terrestrial planet interactions

1980

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A computational model has been developed for the determination of the gasdynamic and magnetic field properties of the solar wind flow around a magnetic planet, such as the earth, or a nonmagnetic planet, such as Venus. The procedures are based on an established single‐fluid, steady, dissipationless, magnetogasdynamic model and are appropriate for the calculation of axisymmetric, supersonic, super‐Alfvénic solar wind flow past a planetary magneto/ionosphere. Sample results are reported for a variety of solar wind and planetary conditions. Some of these are new applications; others are included to show that the new procedures produce the same results as previous procedures when applied to the same conditions. The new methods are completely automated and much more efficient and versatile than those employed heretofore.

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J. R. Spreiter

Hydromagnetic flow around the magnetosphere

Solar wind flow about the outer planets: Gas dynamic modeling of the Jupiter and Saturn bow shocks

Patterns of potential magnetic field merging sites on the dayside magnetopause

A new predictive model for determining solar wind‐terrestrial planet interactions

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