Evolving physical and mechanical rock properties during exposure at Earth's surface

IF 3.1 2区地球科学 Q2 GEOGRAPHY, PHYSICAL

Geomorphology Pub Date : 2025-07-30 DOI:10.1016/j.geomorph.2025.109943

Monica Rasmussen , Martha Cary Eppes , Yang Yuan , Philip G. Meredith , Karin Hofer Apostolidis , Thomas Mitchell , Alex J. Rinehart , Amit Mushkin , Patrick Webb , Valerie Reynolds , Alan J. Hidy , Samantha Berberich , Russell Keanini , Maxwell P. Dahlquist , Tao Xu

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Abstract

Rocks at Earth's surface experience progressive damage due to exposure to environmental conditions. Although environmental damage to rocks is recognized as being time-dependent, our quantitative understanding of its effects on physical and mechanical properties remains limited by field and laboratory studies constrained to short timescales. In this study, we aim to rigorously quantify how these properties evolve under longer natural environmental exposure spanning from the Holocene to the late Pleistocene. We conducted a ‘time series’ analysis of key physical and mechanical rock properties using multiple interior samples from 10 cogenetic granitoid boulders exposed for different amounts of time at two sites in Eastern California, USA. We find that over the late Pleistocene (~30 ka), rocks exhibit porosity increases of 40 ± 4 % and seismic velocity decreases of 7 ± 1 % at both sites. Similarly, over the same time period, rock tensile and compressive strengths declined by an average of 11 ± 4 %, and rock permeability increased on average by 104 ± 50 %. Microscopic analysis of thin sections of the same rocks indicates that microfracture density and intensity also progressively increased over the same timescales. These results suggest that time-dependent fracture propagation due to environmental exposure is likely a central contributor to the observed changes in rock properties. This study provides quantitative documentation that pronounced changes in the physical and mechanical properties of rock progressively occur within thousands of years of exposure.

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暴露在地球表面时岩石物理和机械特性的演化

由于暴露在环境条件下，地球表面的岩石经历了渐进的破坏。虽然环境对岩石的破坏被认为是与时间有关的，但我们对其对物理和机械特性影响的定量理解仍然受到限于短时间尺度的现场和实验室研究的限制。在这项研究中，我们的目标是严格量化这些属性是如何在全新世到晚更新世更长的自然环境暴露下演变的。我们对美国加利福尼亚州东部两个地点的10个同生花岗岩类巨石进行了不同时间暴露的多个内部样本，对岩石的关键物理和机械特性进行了“时间序列”分析。在晚更新世（~30 ka），岩石孔隙度增加了40±4%，地震速度减少了7±1%。同样，在同一时期，岩石抗拉和抗压强度平均下降了11±4%，岩石渗透率平均增加了104±50%。对同一岩石薄片的微观分析表明，在相同的时间尺度上，微裂缝密度和强度也逐渐增加。这些结果表明，由于环境暴露导致的随时间变化的裂缝扩展可能是观察到的岩石性质变化的主要因素。这项研究提供了定量的文件，表明岩石的物理和机械特性在数千年的暴露中逐渐发生显著的变化。

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来源期刊

Geomorphology 地学-地球科学综合

CiteScore

8.00

自引率

10.30%

发文量

309

审稿时长

3.4 months

期刊介绍： Our journal''s scope includes geomorphic themes of: tectonics and regional structure; glacial processes and landforms; fluvial sequences, Quaternary environmental change and dating; fluvial processes and landforms; mass movement, slopes and periglacial processes; hillslopes and soil erosion; weathering, karst and soils; aeolian processes and landforms, coastal dunes and arid environments; coastal and marine processes, estuaries and lakes; modelling, theoretical and quantitative geomorphology; DEM, GIS and remote sensing methods and applications; hazards, applied and planetary geomorphology; and volcanics.