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Magnetization of sinking porous diapirs in planetesimal cores
David Bercovici
*
,
Elvira Mulyukova
*
Corresponding author for this work
Research output
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Contribution to journal
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Article
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peer-review
1
Scopus citations
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Dive into the research topics of 'Magnetization of sinking porous diapirs in planetesimal cores'. Together they form a unique fingerprint.
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Earth and Planetary Sciences
Magnetization
100%
Diapir
100%
Core
100%
Sinking
100%
Protoplanets
100%
Rotating Generator
71%
Solid
42%
Magnetic Field
14%
Solidification
14%
Convection
14%
Distortion
14%
Delamination
14%
Magnetohydrodynamics
14%
Remanent Magnetization
14%
Dipole Moment
14%
Downwelling
14%
Descent
14%
Liquid Metal
14%
Energy Budget
14%
Diapirism
14%
Internal Pressure
14%
Size
14%
Rapid
14%
Condition
14%
Liquid
14%
Addition
14%
Interval
14%
Melt
14%
Meteorite
14%
Physics
Magnetization
100%
Cores
100%
Sinking
100%
Planetesimal
100%
Solid State
60%
Magnetic Fields
20%
Liquid Metals
20%
Viscosity
20%
Solidification
20%
Convection
20%
Internal Pressure
20%
Delamination
20%
Magnetohydrodynamics
20%
Protoplanets
20%
Remanent Magnetization
20%
Asteroid
20%
Liquids
20%
Pulses
20%
Intervals
20%
Meteorites
20%
INIS
porous materials
100%
magnetization
100%
solids
50%
freezing
16%
liquids
16%
size
16%
magnetic fields
16%
pulses
16%
magnetohydrodynamics
16%
viscosity
16%
asteroids
16%
solidification
16%
convection
16%
meteorites
16%
downwelling
16%
liquid metals
16%
dipole moments
16%
energy budgets
16%