正断层控制的地层粒度趋势解析——以希腊Kerinitis gilbert型三角洲为例

IF 2.8 2区地球科学 Q2 GEOSCIENCES, MULTIDISCIPLINARY

Basin Research Pub Date : 2025-01-05 DOI:10.1111/bre.70014

Nahin Rezwan, Alexander C. Whittaker, Jonah S. McLeod, Joel Hook, Sébastien Castelltort, Fritz Schlunegger

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引用次数: 0

摘要

地层学及其相关的粒度记录了源-汇系统随时间的动态行为。沉积物供应和可容纳空间主要控制地层中保存的下游粒度细化。原则上，这些粒度趋势可以反转，以量化这些驱动力的时空变化。本文以希腊哥林多湾早-中更新世Pirgaki-Mermoussia （P-M）断层为例，说明了如何利用粒度和地层厚度来量化断层生长和相互作用。选取了P-M断层上盘隆起的Kerinitis gilbert型三角洲2.5 km长的裸露断崖段作为研究对象。在野外，我们对Kerintis三角洲下部以泛洪面为界的地层单元进行了描画，并测量了它们的厚度，重建了上盘沉降。我们使用Wolman点计数法收集了31个测点的下系统粒度数据。结果表明，晶粒细化速率从11 mm增加到17 mm。Km−1为较低的三角洲沉积物，时间尺度可达120kyr。使用基于自相似性的粒度细化模型，并考虑到在此期间可容纳性生成的最小增量从0.6毫米到1毫米，我们重建了三角洲沉积物供应从大约170立方米到460立方米的增量。将地层厚度测量与粒度细化趋势相结合，可以定量重建断层驱动的可容纳空间和沉积物供应的时间变化，从而展示断层滑动速率的演化。我们发现，在其早期历史中，P-M断层滑动率从1到2 mm年增加，反映了P-M断层段在大约120 kyr的早期相互作用。重建的流域平均侵蚀率约为下盘隆升的20%，这意味着景观对P-M断层的生长有短暂的响应。这些分析表明，在断层控制的沉积系统中，来自良好约束的地质实例的粒度数据可以用于定量重建景观动力学，具有高时空分辨率。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Decoding Normal-Fault Controlled Trends in Stratigraphic Grain Size: Examples From the Kerinitis Gilbert-Type Delta, Greece

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Decoding Normal-Fault Controlled Trends in Stratigraphic Grain Size: Examples From the Kerinitis Gilbert-Type Delta, Greece

Stratigraphy and its associated grain size preserve a record of the dynamic behaviour of source-to-sink systems over time. Sediment supply and available accommodation space primarily control downstream grain-size fining preserved in stratigraphy. In principle, these grain-size trends can be inverted to quantify temporal and spatial variation in these driving forces. Here, we illustrate how grain size and stratigraphic thickness can be used to quantify fault growth and interaction using the early-mid Pleistocene Pirgaki-Mermoussia (P-M) fault, Gulf of Corinth, Greece, as a natural laboratory. A 2.5 km long exposed cliff section of the uplifted Kerinitis Gilbert-type delta, which lies in the hanging wall of the P-M fault, was selected for study. In the field, we traced out stratigraphic units in the lower part of the Kerintis delta, which are bounded by flooding surfaces, and measured their thickness to reconstruct hanging wall subsidence. We collected down-system grain-size data at 31 measurement sites using the Wolman point count method. Our results show the observed grain-size fining rate increase from 11 to 17 mm.km⁻¹ for the lower delta deposits over a timescale of up to 120 kyr. Using a self-similarity-based grain-size fining model and considering a minimum increase in accommodation generation from 0.6 to 1 mm year⁻¹ over this period, we reconstruct an increase in delta sediment supply from ca. 170 to 460 m³ year⁻¹. The integration of stratigraphic thickness measurements with grain-size fining trends enables quantitative reconstruction of temporal variations in fault-driven accommodation space and sediment supply, thereby demonstrating fault slip rate evolution. We show an increase in the P-M fault slip rate during its early history from 1 to 2 mm year⁻¹, reflecting early interaction of the P-M fault segments over ca. 120 kyr. Reconstructed catchment-averaged erosion rates are ca. 20% of the footwall uplift, implying a transient response of the landscape to the P-M fault growth. These analyses demonstrate how grain-size data from a well-constrained geological example can be used to reconstruct landscape dynamics quantitatively in fault-controlled sedimentary systems with high temporal and spatial resolution.

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来源期刊

Basin Research 地学-地球科学综合

CiteScore

7.00

自引率

9.40%

发文量

审稿时长

>12 weeks

期刊介绍： Basin Research is an international journal which aims to publish original, high impact research papers on sedimentary basin systems. We view integrated, interdisciplinary research as being essential for the advancement of the subject area; therefore, we do not seek manuscripts focused purely on sedimentology, structural geology, or geophysics that have a natural home in specialist journals. Rather, we seek manuscripts that treat sedimentary basins as multi-component systems that require a multi-faceted approach to advance our understanding of their development. During deposition and subsidence we are concerned with large-scale geodynamic processes, heat flow, fluid flow, strain distribution, seismic and sequence stratigraphy, modelling, burial and inversion histories. In addition, we view the development of the source area, in terms of drainage networks, climate, erosion, denudation and sediment routing systems as vital to sedimentary basin systems. The underpinning requirement is that a contribution should be of interest to earth scientists of more than one discipline.