P. Clift, Yifan Du, M. Mohtadi, Katharina Pahnke, Mika Sutorius, Philipp Böning
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引用次数: 0
摘要
弧-大陆碰撞是板块构造循环的一个基本阶段,它使大陆地壳得以生长,并通过化学风化作用影响全球气候。澳大利亚与大洋性北海岸山脉-新不列颠弧之间的碰撞始于中新世,导致现代新几内亚高地的隆起。本文利用巴布亚湾的沉积档案重建了这一碰撞的时间演变及其侵蚀和风化影响。锶和钕同位素显示,火成岩弧鲕粒壳的侵蚀占主导地位,在早中新世占总通量的40-70%,在8Ma时上升到80-90%,到现代又下降到72-83%。在上新世,源于澳大利亚的单元加速了侵蚀,就像典型的台湾碰撞一样,但弧形单元而不是大陆单元的侵蚀更大。沉积物的化学蚀变随着时间的推移而加剧,尤其是自 5 Ma 以来,与表明热带风化加剧的高岭石增加相一致。侵蚀主要集中在地势较高的地方,那里的岩浆弧单元更容易暴露出来。沉积物与基岩成分的比较表明,与喜马拉雅山脉的排水沟相比,源地地形从大气中清除二氧化碳的效率更高。 补充材料:https://doi.org/10.6084/m9.figshare.c.7168147
The erosional and weathering response to arc-continent collision in New Guinea
Arc-continent collision is a fundamental stage in the plate tectonic cycle that allows the continental crust to grow and can influence global climate through chemical weathering. Collision between Australia and the oceanic North Coast Range-New Britain Arc began in the Middle Miocene resulting in uplift of the modern New Guinea Highlands. The temporal evolution of this collision and its erosional and weathering impacts is reconstructed here using sedimentary archives from the Gulf of Papua. Sr and Nd isotopes show dominant erosion from igneous arc-ophiolite crust, accounting for ∼40−70% of the total flux in the Early Miocene, and rising to ∼80−90% at 8 Ma, before falling again to 72−83% by the present day. Greater erosion from Australia-derived units accelerated in the Pliocene, like the classic Taiwan collision but with greater erosion from arc rather than continental units. Chemical alteration of the sediment increased through time, especially since ∼5 Ma, consistent with increasing kaolinite indicative of more tropical weathering. Erosion was focused in the high topography where mafic arc units are preferentially exposed. Comparison of sediment with bedrock compositions implies that the source terrains have been more efficient at removing CO
2
from the atmosphere compared to Himalayan drainages.
Supplementary material:
https://doi.org/10.6084/m9.figshare.c.7168147