以极快的海沟退缩模拟俯冲

IF 3.9 2区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS Journal of Geophysical Research: Solid Earth Pub Date : 2024-09-23 DOI:10.1029/2024JB029240
Diandian Peng, Dave R. Stegman
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引用次数: 0

摘要

汤加-克马代克俯冲带在其北端附近表现出最快的海沟后退和辐合。然而,存在一个矛盾:尽管海沟后退速度很快,但汤加板块在 400 千米深度以上仍保持相对陡峭的倾角。板块在 400 千米左右转为平坦,然后再次变陡,直到在 670 千米附近遇到停滞段。尽管这对理解板块动力学具有重要意义,但现有的数值模型还没有成功地证明在快速会聚作用下如何产生如此明显的板块形态。在这里,我们运行的俯冲模型成功地再现了板块几何形态,同时结合了观测到的俯冲速率。我们使用了混合速度边界条件,对弧板块和俯冲板块施加速度,同时允许覆盖板块自由响应。这种方法对于实现模型与观测到的汤加板块之间的良好匹配至关重要。研究结果解释了详细的板块结构是如何对包括海底年龄和地幔粘度在内的物理参数高度敏感的。值得注意的是,非线性流变学是必不可少的,在这种流变学中,位错蠕变在强大的地幔流动下降低了上地幔的粘度。减弱的上地幔使板块下沉速度加快,这就是大倾角的原因。我们的研究结果强调了在数值模型中利用导致极端粘度变化的流变参数,以实现对汤加-克马德克区等复杂俯冲系统的准确描述。我们的研究为进一步研究大洋-大洋俯冲系统开辟了新途径,促进了我们对其在塑造区域和全球构造中的作用的理解。
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Modeling Subduction With Extremely Fast Trench Retreat

The Tonga-Kermadec subduction zone exhibits the fastest observed trench retreat and convergence near its northern end. However, a paradox exists: despite the rapid trench retreat, the Tonga slab maintains a relatively steep dip angle above 400 km depth. The slab turns flat around 400 km, then steepening again until encountering a stagnant segment near 670 km. Despite its significance for understanding slab dynamics, no existing numerical model has successfully demonstrated how such a distinct slab morphology can be generated under the fast convergence. Here we run subduction models that successfully reproduce the slab geometries while incorporating the observed subduction rate. We use a hybrid velocity boundary condition, imposing velocities on the arc and subducting plate while allowing the overriding plate to respond freely. This approach is crucial for achieving a good match between the modeled and observed Tonga slab. The results explain how the detailed slab structure is highly sensitive to physical parameters including the seafloor age and the mantle viscosity. Notably, a nonlinear rheology, where dislocation creep reduces upper mantle viscosity under strong mantle flow, is essential. The weakened upper mantle allows for a faster slab sinking rate, which explains the large dip angle. Our findings highlight the utilizing rheological parameters that lead to extreme viscosity variations within numerical models to achieve an accurate representation of complex subduction systems like the Tonga-Kermadec zone. Our study opens new avenues for further study of ocean-ocean subduction systems, advancing our understanding of their role in shaping regional and global tectonics.

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来源期刊
Journal of Geophysical Research: Solid Earth
Journal of Geophysical Research: Solid Earth Earth and Planetary Sciences-Geophysics
CiteScore
7.50
自引率
15.40%
发文量
559
期刊介绍: The Journal of Geophysical Research: Solid Earth serves as the premier publication for the breadth of solid Earth geophysics including (in alphabetical order): electromagnetic methods; exploration geophysics; geodesy and gravity; geodynamics, rheology, and plate kinematics; geomagnetism and paleomagnetism; hydrogeophysics; Instruments, techniques, and models; solid Earth interactions with the cryosphere, atmosphere, oceans, and climate; marine geology and geophysics; natural and anthropogenic hazards; near surface geophysics; petrology, geochemistry, and mineralogy; planet Earth physics and chemistry; rock mechanics and deformation; seismology; tectonophysics; and volcanology. JGR: Solid Earth has long distinguished itself as the venue for publication of Research Articles backed solidly by data and as well as presenting theoretical and numerical developments with broad applications. Research Articles published in JGR: Solid Earth have had long-term impacts in their fields. JGR: Solid Earth provides a venue for special issues and special themes based on conferences, workshops, and community initiatives. JGR: Solid Earth also publishes Commentaries on research and emerging trends in the field; these are commissioned by the editors, and suggestion are welcome.
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