Measuring the melting curve of iron at super-Earth core conditions

Measuring the melting curve of iron at super-Earth core conditions

The discovery of more than 4500 extrasolar planets has created a need for modeling their interior structure and dynamics. Given the prominence of iron in planetary interiors, we require accurate and precise physical properties at extreme pressure and temperature. A first-order property of iron is it...

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Veröffentlicht in:Science (American Association for the Advancement of Science) 2022-01, Vol.375 (6577), p.202-205
Hauptverfasser: Kraus, Richard G, Hemley, Russell J, Ali, Suzanne J, Belof, Jonathan L, Benedict, Lorin X, Bernier, Joel, Braun, Dave, Cohen, R E, Collins, Gilbert W, Coppari, Federica, Desjarlais, Michael P, Fratanduono, Dayne, Hamel, Sebastien, Krygier, Andy, Lazicki, Amy, Mcnaney, James, Millot, Marius, Myint, Philip C, Newman, Matthew G, Rygg, James R, Sterbentz, Dane M, Stewart, Sarah T, Stixrude, Lars, Swift, Damian C, Wehrenberg, Chris, Eggert, Jon H
Format: Artikel
Sprache:eng
Schlagworte:
Climate
Cosmic radiation
Cosmic rays
Earth core
Extrasolar planets
GEOSCIENCES
Iron
Lasers
Liquid metals
Magnetic fields
Magnetic shielding
Melt temperature
Melting
Melting curve
Melting point
Melting points
Physical properties
Planetary interiors
Planets
Pressure
Radiation
Radiation shielding
Rotating generators
Solidification
Temperature requirements
Terrestrial planets
X-ray diffraction
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Beschreibung
Zusammenfassung:The discovery of more than 4500 extrasolar planets has created a need for modeling their interior structure and dynamics. Given the prominence of iron in planetary interiors, we require accurate and precise physical properties at extreme pressure and temperature. A first-order property of iron is its melting point, which is still debated for the conditions of Earth’s interior. We used high-energy lasers at the National Ignition Facility and in situ x-ray diffraction to determine the melting point of iron up to 1000 gigapascals, three times the pressure of Earth’s inner core. We used this melting curve to determine the length of dynamo action during core solidification to the hexagonal close-packed (hcp) structure. We find that terrestrial exoplanets with four to six times Earth’s mass have the longest dynamos, which provide important shielding against cosmic radiation.
ISSN:0036-8075
1095-9203
DOI:10.1126/science.abm1472