具有大Eu负异常的高分选火成岩中铕同位素分选

IF 1 4区地球科学 Q3 GEOCHEMISTRY & GEOPHYSICS

Geochemical Journal Pub Date : 2021-01-01 DOI:10.2343/geochemj.2.0631

Seung-Gu Lee, Tsuyoshi Tanaka

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引用次数: 3

摘要

高分选花岗岩在地质上与造山事件有关，也与W、Sn、Sb、ree等稀有金属的成矿作用有关。高分异花岗岩的另一个地球化学特征是球粒陨石归一化稀土模式，具有较大的Eu负异常。流纹岩是演化最成熟的火山岩。由于流纹岩主要元素化学组成和球粒陨石归一化稀土模式与高分馏花岗岩相似，因此在比较高分馏花岗岩Eu同位素比值时，流纹岩被认为是高分馏火成岩。Eu是一种非常有趣的稀土元素，因为它有两个氧化态(Eu2+和Eu3+)，而大多数稀土元素在自然界中以三价态(3+)存在。Eu的二价氧化态成为地球和行星系统岩浆演化过程中元素分馏的原因，可以作为岩浆系统氧逸度的指标(Burnham et al.， 2015)。Eu只有两种同位素，151Eu和153Eu。虽然Belli et al.(2007)报道151Eu通过α衰变衰变为147Pm，半衰期T1/2 = 5 × 10 18 yr，但显然151Eu可以被认为是地球和太阳系中的稳定同位素。此外，地质岩石中的Eu同位素比值可能会因地球系统的氧化还原条件而变化(Dauphas et al.， 2014)。具有大Eu负异常的高分选火成岩中铕同位素分选

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Europium isotope fractionation in highly fractionated igneous rocks with large Eu negative anomaly

highly fractionated granite is geologically related to postorogenic events and also to mineralization of rare-metals such as W, Sn, Sb, REEs etc. Another one of the geochemical characteristics of such highly fractionated granite is chondrite-normalized REE pattern with large Eu negative anomaly. In addition, the rhyolite is the most evolved volcanic rock. Since the chemical composition of major elements and chondrite-normalized REE patterns in rhyolite are similar to those of highly fractionated granites, rhyolite was considered highly fractionated igneous rock for comparison of Eu isotope ratio in highly fractionated granite. Eu is a very interesting element of REEs because it has two oxidation states (Eu2+ and Eu3+) whereas most of the rare earth elements exist as the trivalent state (3+) in the nature. The divalent oxidation state of Eu becomes a cause of elemental fractionation during magma evolution in the Earth and planetary system and can be used as an indicator of oxygen fugacity of magma system (Burnham et al., 2015). Eu has only two isotopes, 151Eu and 153Eu. Though Belli et al. (2007) reported that 151Eu decayed to 147Pm by α decay with the half-life T1/2 = 5 × 10 18 yr, apparently, 151Eu can be considered as a stable isotope in earth and solar system. In addition, Eu isotope ratio in geological rocks may vary due to redox condition in Earth system (Dauphas et al., 2014). Europium isotope fractionation in highly fractionated igneous rocks with large Eu negative anomaly

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来源期刊

Geochemical Journal 地学-地球化学与地球物理

CiteScore

1.70

自引率

12.50%

发文量

审稿时长

6 months

期刊介绍： Geochemical Journal is an international journal devoted to original research papers in geochemistry and cosmochemistry. It is the primary journal of the Geochemical Society of Japan. Areas of research are as follows: Cosmochemistry; Mineral and Rock Chemistry; Volcanology and Hydrothermal Chemistry; Isotope Geochemistry and Geochronology; Atmospheric Chemistry; Hydro- and Marine Chemistry; Organic Geochemistry; Environmental Chemistry.