Fachinformationsdienst BAUdigital

A platform for research: civil engineering, architecture and urbanism

    Platinum Partitioning at Low Oxygen Fugacity: Implications for Core Formation Processes

    New search for: E. Medard
    New search for: A. M. Martin
    New search for: K. Righter
    New search for: A. Lanziroti
    New search for: M. Newville

    Highly siderophile elements (HSE = Au, Re, and the Pt-group elements) are tracers of silicate / metal interactions during planetary processes. Since most core-formation models involve some state of equilibrium between liquid silicate and liquid metal, understanding the partioning of highly siderophile elements (HSE) between silicate and metallic melts is a key issue for models of core / mantle equilibria and for core formation scenarios. However, partitioning models for HSE are still inaccurate due to the lack of sufficient experimental constraints to describe the variations of partitioning with key variable like temperature, pressure, and oxygen fugacity. In this abstract, we describe a self-consistent set of experiments aimed at determining the valence of platinum, one of the HSE, in silicate melts. This is a key information required to parameterize the evolution of platinum partitioning with oxygen fugacity.

    Access

    Access via TIB
    Check availability in my library

    Access

    Access via TIB
    Check availability in my library

    Page navigation

    Document information
    Similar titles

    Export, share and cite

    Platinum Partitioning at Low Oxygen Fugacity: Implications for Core Formation Processes

    New search for: E. Medard
    New search for: A. M. Martin
    New search for: K. Righter
    New search for: A. Lanziroti
    New search for: M. Newville

    Highly siderophile elements (HSE = Au, Re, and the Pt-group elements) are tracers of silicate / metal interactions during planetary processes. Since most core-formation models involve some state of equilibrium between liquid silicate and liquid metal, understanding the partioning of highly siderophile elements (HSE) between silicate and metallic melts is a key issue for models of core / mantle equilibria and for core formation scenarios. However, partitioning models for HSE are still inaccurate due to the lack of sufficient experimental constraints to describe the variations of partitioning with key variable like temperature, pressure, and oxygen fugacity. In this abstract, we describe a self-consistent set of experiments aimed at determining the valence of platinum, one of the HSE, in silicate melts. This is a key information required to parameterize the evolution of platinum partitioning with oxygen fugacity.

    Access

    Access via TIB
    Check availability in my library

    Platinum Partitioning at Low Oxygen Fugacity: Implications for Core Formation Processes

    New search for: E. Medard
    New search for: A. M. Martin
    New search for: K. Righter
    New search for: A. Lanziroti
    New search for: M. Newville

    Highly siderophile elements (HSE = Au, Re, and the Pt-group elements) are tracers of silicate / metal interactions during planetary processes. Since most core-formation models involve some state of equilibrium between liquid silicate and liquid metal, understanding the partioning of highly siderophile elements (HSE) between silicate and metallic melts is a key issue for models of core / mantle equilibria and for core formation scenarios. However, partitioning models for HSE are still inaccurate due to the lack of sufficient experimental constraints to describe the variations of partitioning with key variable like temperature, pressure, and oxygen fugacity. In this abstract, we describe a self-consistent set of experiments aimed at determining the valence of platinum, one of the HSE, in silicate melts. This is a key information required to parameterize the evolution of platinum partitioning with oxygen fugacity.

    Access

    Access via TIB
    Check availability in my library

    Access

    Access via TIB
    Check availability in my library

    Page navigation

    Document information
    Similar titles

    Export, share and cite

    Document information
    Title:

    Platinum Partitioning at Low Oxygen Fugacity: Implications for Core Formation Processes

    Contributors:

    E. Medard (author) / A. M. Martin (author) / K. Righter (author) / A. Lanziroti (author) / M. Newville (author)

    Publication date:

    2016

    Size:

    2 pages

    Type of media:

    Report

    Type of material:

    No indication

    Language:

    English

    Keywords:

    Astronomy & Astrophysics , Extraterrestrial Exploration , Planetary cores , Siderophile elements , Silicates , Metal oxides , Liquid metals , Melts (crystal growth) , Equilibrium , Platinum , High pressure , High temperature , Synchrotrons , X ray spectroscopy

    Similar titles

    Platinum Partitioning at Low Oxygen Fugacity: Implications for Core Formation Processes

    Medard, E. / Martin, A. M. / Righter, K. et al. | NTRS | 2016

    A fugacity model for soil vapor extraction

    She, Yuanyin / Sleep, Brent / Mackay, Donald | Taylor & Francis Verlag | 1995

    Fugacity as a Link between Environment and Cover

    Serizawa, A. E. / Machado, M. V. | British Library Conference Proceedings | 2002

    High Fugacity Hydrogen Effects in Beta-21S Titanium Alloy

    Eliezer, D. / Tal-Gutelmacher, E. / Wagner, L. | British Library Online Contents | 2007

    Evaluating fugacity models for trace components in landfill gas

    Shafi, Sophie | Online Contents | 2006

    Back to top