Trace-element mobility in pelite-derived supercritical fluid-melt at subduction-zone conditions

IF 3.5 2区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS
A. G. Sokol, O. A. Kozmenko, A. N. Kruk, S. Y. Skuzovatov, D. V. Kiseleva
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Abstract

The mobility of trace elements in supercritical fluid-melt derived from pelite rich in volatiles has been studied experimentally at pressures from 3.0 to 7.8 GPa and temperatures from 750 to 1090 °С using the diamond trap method. The experiments simulate the conditions of warm and hot subduction, in which pelite either retains the whole inventory of volatiles or releases a fluid in three successive devolatilization steps. The 3.0 GPa and 750 °С runs with pelite rich in volatiles yield a supercritical fluid (SCF) which attains equilibrium with an eclogitic residue bearing phengite and accessory rutile, zircon, and monazite. At ≥5.5 GPa and ≥850 °С, above the second critical endpoint, the SCF transforms into a supercritical fluid-melt (SCFM) which acquires higher concentrations of almost all incompatible trace elements while the mineral assemblage of the equilibrium eclogitic residue remains the same but lacks monazite. The trace-element enrichment of SCFM is most prominent for Ba, Sr, LREE, Th, and U. At the hot subduction conditions, the fluid-melt likewise contains more K, Rb, Zr, and Hf, though LREE contents become lower. The negative Nb anomaly persists in all cases. SCFM has its trace-element composition generally similar to that of hydrous melt derived from oceanic sediments, but contains more REEs and water. Partitioning of LILE, HFSE, and LREE between the SCFM and residue phases mainly depends on the fluid-melt fraction and stability of host phengite, monazite, zircon, and rutile. Thus, sediment-derived SCFM can carry both fluid-mobile and sediment-melt elements to regions of arc- and back-arc magma generation and can translate the negative Nb anomaly inherited from sediment into the magmas. Early devolatilization of pelite increases the stability of monazite and phengite in the residue and provides efficient LREE, K and Rb transport to the mantle depths of ~ 250 km. Effective LREE and Th depletion of UHP metamorphic rocks is possible by SCFM release near peak metamorphic conditions.

Abstract Image

Abstract Image

俯冲带条件下辉绿岩衍生超临界流体-熔体中的痕量元素迁移率
在压力为 3.0 至 7.8 GPa、温度为 750 至 1090 °С 的条件下,使用金刚石陷阱法对富含挥发物的辉绿岩衍生的超临界流体-熔体中微量元素的流动性进行了实验研究。实验模拟了温热俯冲的条件,在这种条件下,辉绿岩要么保留全部挥发物,要么在三个连续的脱溶步骤中释放出一种流体。在 3.0 GPa 和 750 °С 的运行中,富含挥发物的辉绿岩产生了超临界流体(SCF),该流体与含有辉石和附属金红石、锆石和独居石的蚀变残留物达到平衡。在 ≥5.5 GPa 和 ≥850 °С 时,即在第二个临界终点之上,超临界流体转变为超临界流体-熔体(SCFM),其中几乎所有不相容微量元素的浓度都较高,而平衡夕烧残余物的矿物组合保持不变,但缺少独居石。在热俯冲条件下,流体-熔体同样含有更多的 K、Rb、Zr 和 Hf,但 LREE 含量较低。负的 Nb 异常在所有情况下都持续存在。SCFM的痕量元素组成与来自海洋沉积物的含水熔体大致相似,但含有更多的REEs和水。LILE、HFSE和LREE在SCFM和残余相之间的分配主要取决于流体-熔体组分以及宿主辉石、独居石、锆石和金红石的稳定性。因此,沉积物衍生的SCFM可将流体移动元素和沉积物熔融元素携带到弧和弧后岩浆生成区域,并可将沉积物中的负Nb异常转化为岩浆中的负Nb异常。辉绿岩的早期蜕变增加了残留物中独居石和黝帘石的稳定性,并将LREE、K和Rb有效地输送到约250千米的地幔深处。超高压变质岩的有效LREE和Th贫化是可以通过SCFM在峰值变质条件附近释放来实现的。
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来源期刊
Contributions to Mineralogy and Petrology
Contributions to Mineralogy and Petrology 地学-地球化学与地球物理
CiteScore
6.50
自引率
5.70%
发文量
94
审稿时长
1.7 months
期刊介绍: Contributions to Mineralogy and Petrology is an international journal that accepts high quality research papers in the fields of igneous and metamorphic petrology, geochemistry and mineralogy. Topics of interest include: major element, trace element and isotope geochemistry, geochronology, experimental petrology, igneous and metamorphic petrology, mineralogy, major and trace element mineral chemistry and thermodynamic modeling of petrologic and geochemical processes.
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