Please use this identifier to cite or link to this item: http://hdl.handle.net/2248/5467
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dc.contributor.authorHiremath, K. M-
dc.date.accessioned2011-05-16T16:12:35Z-
dc.date.available2011-05-16T16:12:35Z-
dc.date.issued2012-04-
dc.identifier.citationPlanetary and Space Science, Vol. 63–64, pp. 8–14en
dc.identifier.urihttp://hdl.handle.net/2248/5467-
dc.description.abstractRecently planet Mercury-an unexplored territory in our solar system-has been of much interest to the scientific community due to recent flybys of the spacecraft MESSENGER that discovered its intrinsic stationary and large-scale dipole like magnetic field structure with a intensity of ∼ 300 nTesla confirming Mariner 10 observations. In the present study, with the observed constraint of Mercury’s atmospheric magnetic field structure, internal magnetic field structure is modeled as a solution of magnetic diffusion equation. In this study, Mercury’s internal structure mainly consists of a stable stratified fluid core and the convective mantle. For simplicity, magnetic diffusivity in both parts of the structure is considered to be uniform and constant with a value represented by a suitable averages. It is further assumed that vigorous convection in the mantle disposes of the electric currents leading to a very high diffusivity in that region. Thus, in order to satisfy observed atmospheric magnetic field structure, Mercury’s most likely magnetic field structure consists of a solution ofMHD diffusion equation in the core and a combined multipolar (dipole and quadrupole like magnetic field structures embedded in the uniform field) solution of a current free like magnetic field structure in the mantle and in the atmosphere. With imposition of appropriate boundary conditions at the core-mantle boundary for the first two diffusion eigen modes, in order to satisfy the observed field structure, present study puts the constraint on Mercury’s core radius to be ∼ 2000 km. From the estimated magnetic diffusivity and the core radius, it is also possible to estimate the two diffusion eigen modes with their diffusion time scales of the ∼ 8.6 and 3.7 billion yrs respectively suggesting that the planet inherits its present day magnetic field structure from the solar nebula. It is proposed that permanency of such a large-scale magnetic field structure of the planet is attained during Mercury’s early evolutionary history of heavy bombardments by the asteroids and comets supporting the giant impact hypothesis for the formation of Mercuryen
dc.language.isoenen
dc.publisherElsevier B.V.en
dc.relation.urihttp://dx.doi.org/10.1016/j.pss.2011.04.011-
dc.rights© Elsevier B.V.en
dc.subjectMercuryen
dc.subjectMagnetic Field structureen
dc.subjectGiant impactsen
dc.subjectOrigin and Formation of Mercuryen
dc.subjectPlanetary Cratersen
dc.subjectMESSENGER and BepiColombo missionsen
dc.titleMagnetic Field Structure of Mercuryen
dc.typeArticleen
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