C. M. Bertka scite author profile

An iron-sulfur compound (Fe3S2) was synthesized at pressures greater than 14 gigapascals in the system Fe-FeS. The formation of Fe3S2 changed the melting relations from a simple binary eutectic system to a binary system with an intermediate compound that melted incongruently. The eutectic temperature in the system at 14 gigapascals was about 400°C lower than that extrapolated from Usselman's data, implying that previous thermal models of Fe-rich planetary cores could overestimate core temperature. If it is found in a meteorite, the Fe3S2 phase could also be used to infer the minimum size of a parent body.

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Structure and Density of FeS at High Pressure and High Temperature and the Internal Structure of Mars

Fei

Prewitt

Mao

et al. 1995

Science

176

110

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In situ x-ray diffraction measurements revealed that FeS, a possible core material for the terrestrial planets, transforms to a hexagonal NiAs superstructure with axial ratio (c/a) close to the ideal close-packing value of 1.63 at high pressure and high temperature. The high-pressure-temperature phase has shorter Fe-Fe distances than the low-pressure phase. Significant shortening of the Fe-Fe distance would lead to metallization of FeS, resulting in fundamental changes in physical properties of FeS at high pressure and temperature. Calculations using the density of the high-pressure-temperature FeS phase indicate that the martian core-mantle boundary occurs within the silicate perovskite stability field.

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C. M. Bertka

Mineralogy of the Martian interior up to core‐mantle boundary pressures

Structure type and bulk modulus of Fe₃S, a new iron-sulfur compound

High-Pressure Iron-Sulfur Compound, Fe ₃ S ₂ , and Melting Relations in the Fe-FeS System

Structure and Density of FeS at High Pressure and High Temperature and the Internal Structure of Mars

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C. M. Bertka

Mineralogy of the Martian interior up to core‐mantle boundary pressures

Structure type and bulk modulus of Fe3S, a new iron-sulfur compound

High-Pressure Iron-Sulfur Compound, Fe 3 S 2 , and Melting Relations in the Fe-FeS System

Structure and Density of FeS at High Pressure and High Temperature and the Internal Structure of Mars

Contact Info

Product

Resources

About

Structure type and bulk modulus of Fe₃S, a new iron-sulfur compound

High-Pressure Iron-Sulfur Compound, Fe ₃ S ₂ , and Melting Relations in the Fe-FeS System