Effect of silicon on activity coefficients of Bi, Cd, Sn, and Ag in liquid Fe‐Si, and implications for differentiation and core formation

The depletion of volatile siderophile elements (VSE) Sn, Ag, Bi, Cd, and P in mantles of differentiated planetary bodies can be attributed to volatile‐depleted precursor materials (building blocks), fractionation during core formation, fractionation into and retention in sulfide minerals, and/or vol...

Full description

Saved in:
Bibliographic Details
Published in:Meteoritics & planetary science 2019-06, Vol.54 (6), p.1379-1394
Main Authors: Righter, K., Pando, K., Ross, D. K., Righter, M., Lapen, T. J.
Format: Article
Language:English
Subjects:
Activity coefficients
Bismuth
Cadmium
Construction materials
Depletion
Deposition
Earth mantle
Fractionation
Interaction parameters
Iron
Iron meteorites
Liquids
Mars
Meteorites
Nickel
Planet formation
Planetary cores
Planetary mantles
Precursors
Rangefinding
Silicon
Silver
Sulfides
Tin
Upper mantle
Vesta asteroid
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The depletion of volatile siderophile elements (VSE) Sn, Ag, Bi, Cd, and P in mantles of differentiated planetary bodies can be attributed to volatile‐depleted precursor materials (building blocks), fractionation during core formation, fractionation into and retention in sulfide minerals, and/or volatile loss associated with magmatism. Quantitative models to constrain the fractionation due to core formation have not been possible due to the lack of activity and partitioning data. Interaction parameters in Fe‐Si liquids have been measured at 1 GPa, 1600 °C and increase in the order Cd (~6), Ag (~10), Sn (~28), Bi (~46), and P (~58). These large and positive values contrast with smaller and negative values in Fe‐S liquids indicating that any chalcophile behavior exhibited by these elements will be erased by dissolution of a small amount of Si in the metallic liquid. A newly updated activity model is applied to Earth, Mars, and Vesta. Five elements (P, Zn, Sn, Cd, and In) in Earth's primitive upper mantle can largely be explained by metal‐silicate equilibrium at high PT conditions where the core‐forming metal is a Fe‐Ni‐S‐Si‐C metallic liquid, but two other—Ag and Bi—become overabundant during core formation and require a removal mechanism such as late sulfide segregation. All of the VSE in the mantle of Mars are consistent with core formation in a volatile element depleted body, and do not require any additional processes. Only P and Ag in Vesta's mantle are consistent with combined core formation and volatile‐depleted precursors, whereas the rest require accretion of chondritic or volatile‐bearing material after core formation. The concentrations of Zn, Ag, and Cd modeled for Vesta's core are similar to the concentration range measured in magmatic iron meteorites indicating that these volatile elements were already depleted in Vesta's precursor materials.
ISSN:1086-9379
1945-5100
DOI:10.1111/maps.13285