岩石崩落造成基岩切变和沟道化的机理模型与实验

IF 3.5 2区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY
A. R. Beer, J. N. Fischer, T. P. Ulizio, Z. Ma, Z. Sun, M. P. Lamb
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引用次数: 0

摘要

落石和岩崩在地球上的陡峭地形中很常见,在月球和火星等其他行星体上也可能发生。由于撞击的岩石在滚落和反弹到山下的过程中会破坏裸露的基岩,因此,即使在没有水的情况下,落石也可能是陡峭地形的重要侵蚀因素。我们利用岩石在重力作用下的弹道轨迹,提出了岩石坠落驱动基岩侵蚀的新理论。我们利用倾斜基岩模拟物上的落石实验室实验对这一理论进行了校准。实验和模型都证明,基岩山坡会受到干式落石的磨损,即使坡度低于倾角,这取决于基岩的粗糙度。在没有水的情况下,落石的磨损和地形转向之间的反馈作用会产生类似通道的形式,如基岩槽。颗粒大小对磨损率和冲出距离有主要影响,而山坡角度的影响相对较小。落石迁移对基岩的粗糙度很敏感;摩擦角大的地形会将岩石困住,形成岩石覆盖斑块,从而影响后续的落石路径。我们的研究结果表明,干落石在侵蚀和疏导地球和其他行星上的陡峭岩石地形(如月球和火星上的陨石坑退化)方面发挥着重要作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

A Mechanistic Model and Experiments on Bedrock Incision and Channelization by Rockfall

A Mechanistic Model and Experiments on Bedrock Incision and Channelization by Rockfall

Rockfall and rock avalanches are common in steep terrain on Earth and potentially on other planetary bodies such as the Moon and Mars. Since impacting rocks can damage exposed bedrock as they roll and bounce downhill, rockfall might be an important erosive agent in steep landscapes, even in the absence of water. We developed a new theory for rockfall-driven bedrock abrasion using the ballistic trajectories of rocks transported under gravity. We calibrated this theory using laboratory experiments of rockfall over an inclined bedrock simulant. Both the experiments and the model demonstrate that bedrock hillslopes can be abraded by dry rockfall, even at gradients below the angle of repose, depending on the bedrock roughness. Feedback between abrasion and topographic steering of rockfall can produce channel-like forms, such as bedrock chutes, in the absence of water. Particle size has a dominant influence on abrasion rates and runout distances, while the hillslope angle has a comparatively minor influence. Rockfall transport is sensitive to bedrock roughness; terrain with high friction angles can trap rocks creating patches of rock cover that affect subsequent rockfall pathways. Our results suggest that dry rockfall can play an important role in eroding and channelizing steep, rocky terrain on Earth and other planets, such as crater degradation on the Moon and Mars.

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来源期刊
Journal of Geophysical Research: Earth Surface
Journal of Geophysical Research: Earth Surface Earth and Planetary Sciences-Earth-Surface Processes
CiteScore
6.30
自引率
10.30%
发文量
162
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