钙钛矿在地球深部。

Perovskite in Earth's deep interior.

机构信息

Earth-Life Science Institute, Tokyo Institute of Technology, Meguro, Tokyo 152-8550, Japan.

Department of Earth and Planetary Science, Graduate School of Science, The University of Tokyo, Bunkyo, Tokyo 113-0033, Japan.

出版信息

Science. 2017 Nov 10;358(6364):734-738. doi: 10.1126/science.aam8561.

DOI:10.1126/science.aam8561

PMID:29123059

Abstract

Silicate perovskite-type phases are the most abundant constituent inside our planet and are the predominant minerals in Earth's lower mantle more than 660 kilometers below the surface. Magnesium-rich perovskite is a major lower mantle phase and undergoes a phase transition to post-perovskite near the bottom of the mantle. Calcium-rich perovskite is proportionally minor but may host numerous trace elements that record chemical differentiation events. The properties of mantle perovskites are the key to understanding the dynamic evolution of Earth, as they strongly influence the transport properties of lower mantle rocks. Perovskites are expected to be an important constituent of rocky planets larger than Mars and thus play a major role in modulating the evolution of terrestrial planets throughout the universe.

摘要

硅酸盐钙钛矿型相是我们星球上最丰富的组成部分，也是地球下地幔中超过 660 公里以下表面的主要矿物。富含镁的钙钛矿是下地幔的主要相，并在地幔底部附近经历向钙钛矿后相的相变。富含钙的钙钛矿比例较小，但可能含有许多记录化学分异事件的微量元素。地幔钙钛矿的性质是理解地球动态演化的关键，因为它们强烈影响下地幔岩石的输运性质。钙钛矿预计将是火星等更大的岩石行星的重要组成部分，因此在调节整个宇宙中类地行星的演化方面发挥着重要作用。

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钙钛矿在地球深部。

Perovskite in Earth's deep interior.

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