Coevolving edge rounding and shape of glacial erratics: the case of Shap granite, UK

IF 2.8 2区 地球科学 Q2 GEOGRAPHY, PHYSICAL Earth Surface Dynamics Pub Date : 2024-02-26 DOI:10.5194/esurf-12-381-2024
Paul A. Carling
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Abstract

Abstract. The size distributions and the shapes of detrital rock clasts can shed light on the environmental history of the clast assemblages and the processes responsible for clast comminution. For example, mechanical fracture due to the stresses imposed on a basal rock surface by a body of flowing glacial ice releases initial “parent” shapes of large blocks of rock from an outcrop, which then are modified by the mechanics of abrasion and fracture during subglacial transport. The latter processes produce subsequent generations of shapes, possibly distinct in form from the parent blocks. A complete understanding of both the processes responsible for block shape changes and the trends in shape adjustment with time and distance away from the source outcrop is lacking. Field data on edge rounding and shape changes of Shap granite blocks (dispersed by Devensian ice eastwards from the outcrop) are used herein to explore the systematic changes in block form with distance from the outcrop. The degree of edge rounding for individual blocks increases in a punctuated fashion with the distance from the outcrop as blocks fracture repeatedly to introduce new fresh unrounded edges. In contrast, block shape is conservative, with parent blocks fracturing to produce self-similar “child” shapes with distance. Measured block shapes evolve in accord with two well-known models for block fracture mechanics – (1) stochastic and (2) silver ratio models – towards one or the other of these two attractor states. Progressive reduction in block size, in accord with fracture mechanics, reflects the fact that most blocks were transported at the sole of the ice mass and were subject to the compressive and tensile forces of the ice acting on the stoss surfaces of blocks lying against a bedrock or till surface. The interpretations might apply to a range of homogeneous hard rock lithologies.
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冰川岩屑的边缘圆化和形状的共同演变:英国沙普花岗岩的案例
摘要岩石碎屑的大小分布和形状可以揭示碎屑组合的环境历史以及碎屑的粉碎过程。例如,流动的冰川冰体对基底岩石表面施加的应力所导致的机械断裂,会从露头岩石中释放出大块岩石的初始 "母体 "形状,然后在冰川下搬运过程中通过机械磨损和断裂改变这些形状。后一过程会产生后续的形状,这些形状可能与母岩块的形状截然不同。对于造成岩块形状变化的过程,以及随着时间和远离源露头的距离而发生形状调整的趋势,我们还缺乏全面的了解。本文利用沙普花岗岩岩块(由德文西亚冰川从露头向东散布)边缘变圆和形状变化的实地数据,探讨了岩块形状随距离露头的远近而发生的系统性变化。单个岩块的边缘磨圆程度随着与露头距离的增加而呈点状增加,因为岩块会反复断裂,从而产生新的未磨圆边缘。与此相反,岩块形状是保守的,母岩块随着距离的增加而断裂,产生自相似的 "子 "岩块形状。测量到的岩块形状与两种著名的岩块断裂力学模型--(1)随机模型和(2)银比模型--一致,都是朝着这两种吸引状态中的一种或另一种演变。根据断裂力学,块体尺寸的逐渐减小反映了这样一个事实,即大多数块体都是在冰体底部搬运的,并受到冰体作用在块体表面的压缩力和拉伸力的影响,这些块体的表面紧贴基岩或岩层表面。这些解释可能适用于一系列均质硬岩岩性。
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来源期刊
Earth Surface Dynamics
Earth Surface Dynamics GEOGRAPHY, PHYSICALGEOSCIENCES, MULTIDISCI-GEOSCIENCES, MULTIDISCIPLINARY
CiteScore
5.40
自引率
5.90%
发文量
56
审稿时长
20 weeks
期刊介绍: Earth Surface Dynamics (ESurf) is an international scientific journal dedicated to the publication and discussion of high-quality research on the physical, chemical, and biological processes shaping Earth''s surface and their interactions on all scales.
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