| Literature DB >> 32414927 |
Guillaume Morard1,2, Jean-Alexis Hernandez3,4, Marco Guarguaglini3, Riccardo Bolis3, Alessandra Benuzzi-Mounaix3, Tommaso Vinci3, Guillaume Fiquet5, Marzena A Baron5, Sang Heon Shim6, Byeongkwan Ko6, Arianna E Gleason7,8, Wendy L Mao7, Roberto Alonso-Mori8, Hae Ja Lee8, Bob Nagler8, Eric Galtier8, Dimosthenis Sokaras8, Siegfried H Glenzer8, Denis Andrault9, Gaston Garbarino10, Mohamed Mezouar10, Anja K Schuster11, Alessandra Ravasio3.
Abstract
Properties of liquid silicates under high-pressure and high-temperature conditions are critical for modeling the dynamics and solidification mechanisms of the magma ocean in the early Earth, as well as for constraining entrainment of melts in the mantle and in the present-day core-mantle boundary. Here we present in situ structural measurements by X-ray diffraction of selected amorphous silicates compressed statically in diamond anvil cells (up to 157 GPa at room temperature) or dynamically by laser-generated shock compression (up to 130 GPa and 6,000 K along the MgSiO3 glass Hugoniot). The X-ray diffraction patterns of silicate glasses and liquids reveal similar characteristics over a wide pressure and temperature range. Beyond the increase in Si coordination observed at 20 GPa, we find no evidence for major structural changes occurring in the silicate melts studied up to pressures and temperatures exceeding Earth's core mantle boundary conditions. This result is supported by molecular dynamics calculations. Our findings reinforce the widely used assumption that the silicate glasses studies are appropriate structural analogs for understanding the atomic arrangement of silicate liquids at these high pressures.Entities:
Keywords: XFEL diffraction; amorphous silicates; high pressure; shock compression; static compression
Year: 2020 PMID: 32414927 DOI: 10.1073/pnas.1920470117
Source DB: PubMed Journal: Proc Natl Acad Sci U S A ISSN: 0027-8424 Impact factor: 11.205