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Magnetization of sinking porous diapirs in planetesimal cores
David Bercovici
*
,
Elvira Mulyukova
*
Corresponding author for this work
Earth and Planetary Sciences
Research output
:
Contribution to journal
›
Article
›
peer-review
2
Scopus citations
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Keyphrases
Planetesimals
100%
Magnetization
100%
Diapir
100%
Seepage
50%
Dynamo
50%
Delaminating
25%
Solid Materials
12%
Delamination
12%
Small Bodies
12%
Downwelling
12%
Asteroids
12%
Flow around
12%
Liquid Metal
12%
Convection
12%
High Viscosity
12%
Dipole Moment
12%
Field Lines
12%
Internal Pressure
12%
Poloidal Field
12%
Remanent Magnetization
12%
Intermittent Pulse
12%
Solidification Path
12%
Partial Melt
12%
Remnant Magnetization
12%
Background Fields
12%
Field Distortion
12%
Energy Budget
12%
Freezing Front
12%
Background Magnetic Field
12%
Solidified Material
12%
Magnetohydrodynamic Theory
12%
Core Dynamo
12%
Diapirism
12%
Engineering
Porosity
100%
Remnant Magnetization
33%
Solidification Front
33%
Energy Engineering
33%
Field Line
33%
Delamination
33%
Magnetic Field
33%
Internal Pressure
33%
Dipole Moment
33%
Liquid Metal
33%
Magnetohydrodynamics
33%
Earth and Planetary Sciences
Diapir
100%
Protoplanets
100%
Porosity
100%
Magnetohydrodynamics
12%
Remanent Magnetization
12%
Downwelling
12%
Energy Budget
12%
Diapirism
12%
Internal Pressure
12%
Dipole Moment
12%
Delamination
12%
Liquid Metal
12%
Physics
Protoplanets
100%
Porosity
100%
Delamination
25%
Magnetic Field
25%
Magnetohydrodynamics
25%
Dipole Moment
25%
Internal Pressure
25%
Remanent Magnetization
25%
Liquid Metal
25%