All-optical measurements of MORB-glass density at high pressure hint at a stiffness-composition relation in silicate glasses

IF 3.6 2区地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS

Chemical Geology Pub Date : 2025-09-21 DOI:10.1016/j.chemgeo.2025.123066

Sergey S. Lobanov , Sergio Speziale , Ilya Kupenko , Vladimir Roddatis , Louis Hennet , Séverine Brassamin , Konstantin Solovev , Lukas Schifferle

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引用次数: 0

Abstract

The density of silicate melts at high pressure determined the efficiency of gravitational differentiation in the solidifying magma ocean and thus the starting conditions for the Earth's evolution. The denisty also controls the migration of melts in the lithosphere and their stabilization in the transition zone and near the core mantle boundary. Yet, no density systematic exists for melts across the pressure range of the mantle. This is primarily because of severe experimental difficulties associated with measuring the density of silicate liquids at mantle pressures and temperatures (tiny sample size, melt chemical reactivity, lack of crystalline structure). The use of glasses as proxies of melts at high pressure lifts some but not all of these challenges, and may prove important in developing theoretical models of melts physical behavior at high pressures. Here we report on the density of MORB glass up to 32.3 GPa at room temperature measured by the recently developed all-optical method in a diamond anvil cell. The comparison of the MORB glass density to that for other basaltic glasses reported in the literature reveals contradictions, similarly to those existing between data available for MORB-like melts, which underscore the need for consistent, systematic melt and glass density measurements at high pressure across a broad compositional space. More broadly, the compression behavior of MORB and other basaltic glasses, SiO₂, MgSiO₃, and Mg₂SiO₄ glasses suggests that the incorporation of SiO₂ and/or large network-modifiers (larger than Mg) softens the glass (smaller isothermal bulk modulus and its pressure derivative). Future all-optical measurements of glass density may provide fundamental, critical input to develop models of complex glasses and melts physical properties, and help assessing the solidification of the primordial magma ocean, the initiation and development of physical and chemical heterogeneity in the mantle, and the migration or stabilization of melts at different levels in the deep Earth.

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高压下morb -玻璃密度的全光学测量暗示了硅酸盐玻璃的刚度-成分关系

高压下硅酸盐熔体的密度决定了凝固岩浆海洋中重力分馏的效率，从而决定了地球演化的起始条件。密度还控制着岩石圈内熔体的迁移及其在过渡带和核幔边界附近的稳定。然而，在整个地幔压力范围内，不存在熔体的密度系统。这主要是因为在地幔压力和温度下测量硅酸盐液体的密度存在严重的实验困难（样本量小、熔体化学反应性差、缺乏晶体结构）。使用玻璃作为高压下熔体的代用物解决了部分但不是全部的挑战，并且可能对开发高压下熔体物理行为的理论模型很重要。在此，我们报道了用最近开发的全光学方法在金刚石砧细胞中测量室温下高达32.3 GPa的MORB玻璃密度。MORB玻璃密度与文献中报道的其他玄武岩玻璃密度的比较揭示了矛盾，类似于MORB类熔体现有数据之间存在的矛盾，这强调了在广泛成分空间的高压下进行一致、系统的熔体和玻璃密度测量的必要性。更广泛地说，MORB和其他玄武岩玻璃、SiO2、MgSiO3和Mg2SiO4玻璃的压缩行为表明，SiO2和/或大型网络改性剂（大于Mg）的掺入软化了玻璃（较小的等温体积模量及其压力导数）。未来对玻璃密度的全光学测量可能为建立复杂玻璃和熔体物理性质的模型提供基础和关键的输入，并有助于评估原始岩浆海洋的凝固，地幔中物理和化学非均质性的开始和发展，以及地球深部不同水平熔体的迁移或稳定。

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来源期刊

Chemical Geology 地学-地球化学与地球物理

CiteScore

7.20

自引率

10.30%

发文量

374

审稿时长

3.6 months

期刊介绍： Chemical Geology is an international journal that publishes original research papers on isotopic and elemental geochemistry, geochronology and cosmochemistry. The Journal focuses on chemical processes in igneous, metamorphic, and sedimentary petrology, low- and high-temperature aqueous solutions, biogeochemistry, the environment and cosmochemistry. Papers that are field, experimentally, or computationally based are appropriate if they are of broad international interest. The Journal generally does not publish papers that are primarily of regional or local interest, or which are primarily focused on remediation and applied geochemistry. The Journal also welcomes innovative papers dealing with significant analytical advances that are of wide interest in the community and extend significantly beyond the scope of what would be included in the methods section of a standard research paper.