Abstract
The preparation process of natural earthquakes is still difficult to quantify and remains a subject of debate even with modern observational techniques. Here, we show that foreshock activity can shed light on understanding the earthquake preparation process based on results of meter-scale rock friction experiments. Experiments were conducted under two different fault surface conditions before each run: less heterogeneous fault without pre-existing gouge and more heterogeneous fault with pre-existing gouge. The results show that fewer foreshocks occurred along the less heterogeneous fault and were driven by preslip; in contrast, more foreshocks with a lower b value occurred along the more heterogeneous fault and showed features of cascade-up. We suggest that the fault surface condition and the stress redistribution caused by the ongoing fault slip mode control the earthquake preparation process, including the behavior of foreshock activity. Our findings imply that foreshock activity can be a key indicator for probing the fault conditions at present and in the future, and therefore useful for assessing earthquake hazard.
Highlights
The preparation process of natural earthquakes is still difficult to quantify and remains a subject of debate even with modern observational techniques
The results show that fewer foreshocks occurred along the less heterogeneous fault and were driven by preslip; in contrast, more foreshocks with a lower b value occurred along the more heterogeneous fault and showed features of cascade-up
We suggest that the fault surface condition and the stress redistribution caused by the ongoing fault slip mode control the earthquake preparation process, including the behavior of foreshock activity
Summary
The preparation process of natural earthquakes is still difficult to quantify and remains a subject of debate even with modern observational techniques. One is the preslip model: quasi-static slow slip initiates first, the slipped area expands at an accelerated rate, and it eventually leads to an unstable fast rupture over the whole fault area. This process has been well studied in theory, modeling[2,3,4,5,6], and laboratory experiments[7,8,9,10,11,12]. Foreshocks triggered by preslip were observed on a large-scale laboratory fault[8], which might be an analog to the foreshock sequence preceding some natural earthquakes[25,26,27]
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