Electrical conductivity of anhydrous and hydrous gabbroic melt under high temperature and high pressure: implications for the high-conductivity anomalies in the mid-ocean ridge region

IF 3.2 2区地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS

Solid Earth Pub Date : 2023-08-15 DOI:10.5194/se-14-847-2023

Mengqi Wang, Lidong Dai, Haiying Hu, Ziming Hu, Chenxin Jing, Chuanyu Yin, Song-Shan Luo, Jinhua Lai

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Abstract

Abstract. The electrical conductivity of gabbroic melt with four different water contents (i.e., 0 %, 2.59 wt %, 5.92 wt %, and 8.32 wt %) was measured at temperatures of 873–1373 K and pressures of 1.0–3.0 GPa using a YJ-3000t multi-anvil high-pressure apparatus and Solartron-1260 impedance spectroscopy analyzer. At a fixed water content of 2.59 wt %, the electrical conductivity of the sample slightly decreased with increasing pressure in the temperature range of 873–1373 K, and its corresponding activation energy and activation volume were determined as 0.87 ± 0.04 eV and −1.98 ± 0.02 cm3 molec.−1, respectively. Under the certain conditions of 873–1373 K and 1.0 GPa, the electrical conductivity of the gabbroic melts tends to gradually increase with a rise in water content from 0 wt % to 8.32 wt %, and the activation enthalpy decreases from 0.93 to 0.63 eV accordingly. Furthermore, functional relation models for the electrical conductivity of gabbroic melts with variations of temperature, pressure, and water content were constructed at high-temperature and high-pressure conditions. In addition, the dependence relation of the electrical conductivity of melts with the degree of depolymerization was explored under conditions of four different water contents at 1373 K and 1.0 GPa, and three previously available reported results on those of representative calc-alkaline igneous rock melts (i.e., dacitic melt, basaltic melt, and andesitic melt) were compared in detail. In combination with our presently acquired electrical conductivity data on gabbroic melt with four different water contents and the available data on polycrystalline olivine, the electrical conductivity of a gabbroic melt–olivine system with variation of the volume percentage of anhydrous and hydrous melts was successfully constructed by using the typical Hashin–Shtrikman upper-bound model. In light of the electrical conductivity of the gabbroic melt–olivine system with previous magnetotelluric (MT) results, we find that anhydrous and hydrous gabbroic melts can be employed to reasonably interpret the high-conductivity anomalies in the Mohns Ridge of the Arctic Ocean.

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高温高压下无水和含水辉长岩熔体的电导率:对洋中脊区域高电导率异常的启示

摘要在873-1373 K温度和1.0-3.0 GPa压力下，采用yj -3000t型多顶柱高压测井仪和Solartron-1260型阻抗光谱分析仪测量了四种不同含水量(0 %、2.59 wt %、5.92 wt %和8.32 wt %)辉长岩熔体的电导率。在固定含水量为2.59 wt %时，在873-1373 K温度范围内，样品的电导率随压力的增加而略有下降，其对应的活化能和活化体积分别为0.87±0.04 eV和- 1.98±0.02 cm3分子。−1,分别。在873 ~ 1373 K和1.0 GPa条件下，随着含水量从0 wt %增加到8.32 wt %，辉长岩熔体的电导率呈逐渐增加的趋势，激活焓从0.93 eV降低到0.63 eV。在高温高压条件下，建立了辉长岩熔体电导率随温度、压力和含水量变化的函数关系模型。此外，在1373 K和1.0 GPa条件下，探讨了四种不同含水量条件下熔体电导率与解聚程度的关系，并对具有代表性的钙碱性火成岩熔体(即英安岩熔体、玄武岩熔体和安山岩熔体)的三个已有报道的结果进行了详细的比较。结合已有的四种不同含水量辉长岩熔体的电导率数据和多晶橄榄石的电导率数据，利用典型的hashn - shtrikman上界模型，成功地构建了随无水和含水熔体体积百分比变化的辉长岩熔体-橄榄石体系的电导率。结合辉长岩熔体-橄榄石体系的电导率和以往的大地电磁结果，发现无水和含水辉长岩熔体可以合理地解释北冰洋莫恩斯脊的高电导率异常。

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来源期刊

Solid Earth GEOCHEMISTRY & GEOPHYSICS-

CiteScore

6.90

自引率

8.80%

发文量

审稿时长

4.5 months

期刊介绍： Solid Earth (SE) is a not-for-profit journal that publishes multidisciplinary research on the composition, structure, dynamics of the Earth from the surface to the deep interior at all spatial and temporal scales. The journal invites contributions encompassing observational, experimental, and theoretical investigations in the form of short communications, research articles, method articles, review articles, and discussion and commentaries on all aspects of the solid Earth (for details see manuscript types). Being interdisciplinary in scope, SE covers the following disciplines: geochemistry, mineralogy, petrology, volcanology; geodesy and gravity; geodynamics: numerical and analogue modeling of geoprocesses; geoelectrics and electromagnetics; geomagnetism; geomorphology, morphotectonics, and paleoseismology; rock physics; seismics and seismology; critical zone science (Earth''s permeable near-surface layer); stratigraphy, sedimentology, and palaeontology; rock deformation, structural geology, and tectonics.