Detection of thin film phase transformations at high-pressure and high-temperature in a diamond anvil cell

Meryem Berrada; Genzhi Hu; Dongyuan Zhou; Siheng Wang; Phuong Q. H. Nguyen; Dongzhou Zhang; Vitali Prakapenka; Stella Chariton; Bin Chen; Jie Li; Jason D. Nicholas

doi:10.1038/s43247-024-01234-9

Communications Earth & Environment (Feb 2024)

Detection of thin film phase transformations at high-pressure and high-temperature in a diamond anvil cell

Meryem Berrada,
Genzhi Hu,
Dongyuan Zhou,
Siheng Wang,
Phuong Q. H. Nguyen,
Dongzhou Zhang,
Vitali Prakapenka,
Stella Chariton,
Bin Chen,
Jie Li,
Jason D. Nicholas

Affiliations

Meryem Berrada: Hawaii Institute of Geophysics and Planetology, University of Hawaii at Manoa
Genzhi Hu: Chemical Eng. & Materials Science Department, Michigan State University
Dongyuan Zhou: Earth and Environmental Sciences Department, University of Michigan
Siheng Wang: Hawaii Institute of Geophysics and Planetology, University of Hawaii at Manoa
Phuong Q. H. Nguyen: Hawaii Institute of Geophysics and Planetology, University of Hawaii at Manoa
Dongzhou Zhang: Hawaii Institute of Geophysics and Planetology, University of Hawaii at Manoa
Vitali Prakapenka: Center for Advanced Radiation Sources, The University of Chicago
Stella Chariton: Center for Advanced Radiation Sources, The University of Chicago
Bin Chen: Hawaii Institute of Geophysics and Planetology, University of Hawaii at Manoa
Jie Li: Earth and Environmental Sciences Department, University of Michigan
Jason D. Nicholas: Chemical Eng. & Materials Science Department, Michigan State University

DOI: https://doi.org/10.1038/s43247-024-01234-9
Journal volume & issue: Vol. 5, no. 1
pp. 1 – 10

Abstract

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Abstract Quantifying how grain size and/or deviatoric stress impact (Mg,Fe)2SiO4 phase stability is critical for advancing our understanding of subduction processes and deep-focus earthquakes. Here, we demonstrate that well-resolved X-ray diffraction patterns can be obtained on nano-grained thin films within laser-heated diamond anvil cells (DACs) at hydrostatic pressures up to 24 GPa and temperatures up to 2300 K. Combined with well-established literature processes for tuning thin film grain size, biaxial stress, and substrate identity, these results suggest that DAC-loaded thin films can be useful for determining how grain size, deviatoric stress, and/or the coexistence of other phases influence high-pressure phase stability. As such, this novel DAC-loaded thin film approach may find use in a variety of earth science, planetary science, solid-state physics, and materials science applications.

Published in Communications Earth & Environment

ISSN: 2662-4435 (Online)
Publisher: Nature Portfolio
Country of publisher: United Kingdom
LCC subjects: Science: Geology; Geography. Anthropology. Recreation: Environmental sciences
Website: https://www.nature.com/commsenv/

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