IODP Drilling at the Godzilla Megamullion: The Nature of the Backarc Basin Lower Crust and Upper Mantle

IF 0.2 Q4 GEOGRAPHY, PHYSICAL
Y. Ohara
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引用次数: 3

Abstract

― ― Abstract A significant fraction of the ocean floor is created in back-arc basins, where water plays a major role in generating back-arc basin basalts, contrasting strikingly with magmatic processes at mid-oceanic ridges. Furthermore, much of our understanding of all of the oceanic crust comes from ophiolites, which are largely attributed to supra-subduction zone environments. Therefore, studying the back-arc basin lower crust and uppermost mantle is arguably important, contribut-ing to the overall geology of the oceanic crust. The Godzilla Megamullion, located in the extinct Parece Vela Basin in the Philippine Sea, is the largest known oceanic core complex. It is an elongated massif with a distinct corrugated surface consisting of several individual domal highs. It records the secular evolution of the mantle melting beneath a dying back-arc spreading ridge along the length of the megamullion surface. Furthermore, strong heterogeneity in the P-wave velocity structure is observed along the length of the megamullion, with a normal oceanic crust-like structure in the distal ( i.e., near breakaway ) to medial parts, and a shallow high-velocity body in the proximal ( i.e, near termination ) part. The Godzilla Megamullion should arguably be the best place in the world to study the architecture of the back-arc basin lower crust and uppermost mantle, and the actual crust/mantle boundary through the International Ocean Discovery Program ( IODP ) . By locating three 400- to 800 m-deep drill holes along its length, key data are obtained to better understand and constrain the composition of the back-arc basin oceanic crust and uppermost mantle, as well as the architecture of oceanic core complexes. The extinct backarc basin environment at the Godzilla Megamullion provides a further unique opportunity to explore life in an oceanic crust after extinction of its hydrothermal activity.
哥斯拉巨型金矿的碘含量钻探:弧后盆地下地壳和上地幔的性质
很大一部分洋底形成于弧后盆地,水在弧后盆地玄武岩的形成中起着主要作用,与洋中脊的岩浆作用形成鲜明对比。此外,我们对所有海洋地壳的理解大部分来自蛇绿岩,这在很大程度上归因于超俯冲带环境。因此,对弧后盆地下地壳和上地幔的研究具有重要意义,有助于海洋地壳的整体地质研究。位于菲律宾海已灭绝的Parece Vela盆地的哥斯拉巨兽是已知最大的海洋核群。它是一个细长的地块,具有明显的波纹表面,由几个单独的丘状高地组成。它记录了地幔融化的长期演变,在一个濒临消亡的弧后伸展脊下,沿着巨大的表面延伸。此外,纵波速度结构沿巨节段长度具有很强的非均匀性,在远端(即接近分离)至中部为正常的海洋地壳状结构,而在近端(即接近终止)部分为浅层高速体。通过国际海洋发现计划(International Ocean Discovery Program, IODP)研究弧后盆地下地壳和上地幔的构造,以及实际的壳幔边界,可以说是世界上最好的地方。通过沿其长度定位3个400 ~ 800 m深的钻孔,获得了更好地了解和约束弧后盆地洋壳、上地幔组成及洋核杂岩构造的关键数据。哥斯拉巨巨的弧后盆地环境为探索热液活动消失后的海洋地壳中的生命提供了进一步的独特机会。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
1.50
自引率
33.30%
发文量
28
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