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Spin state and moment of inertia of Venus

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 نشر من قبل Jean-Luc Margot
 تاريخ النشر 2021
  مجال البحث فيزياء
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Fundamental properties of the planet Venus, such as its internal mass distribution and variations in length of day, have remained unknown. We used Earth-based observations of radar speckles tied to the rotation of Venus obtained in 2006-2020 to measure its spin axis orientation, spin precession rate, moment of inertia, and length-of-day variations. Venus is tilted by 2.6392 $pm$ 0.0008 degrees ($1sigma$) with respect to its orbital plane. The spin axis precesses at a rate of 44.58 $pm$ 3.3 arcseconds per year ($1sigma$), which gives a normalized moment of inertia of 0.337 $pm$ 0.024 and yields a rough estimate of the size of the core. The average sidereal day on Venus in the 2006-2020 interval is 243.0226 $pm$ 0.0013 Earth days ($1sigma$). The spin period of the solid planet exhibits variations of 61 ppm ($sim$20 minutes) with a possible diurnal or semidiurnal forcing. The length-of-day variations imply that changes in atmospheric angular momentum of at least $sim$4% are transferred to the solid planet.



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