Using small events to constrain the physical mechanism governing slow slip
Lead Research Organisation:
University of Oxford
Department Name: Earth Sciences
Abstract
In conventional models, faults can slip in one of two ways: steadily at rates near plate rate or episodically in earthquakes. However, in the past two decades researchers have discovered another behaviour: slow slip events. In slow slip events, large portions of the plate interface slip accelerate periodically but then stall long before reaching seismic slip rates. The puzzle is why: what physical mechanism allows for slow yet episodic slip?
Episodic slow slip is important to understand because slow slip events occur just below the locked zone, which hosts hazardous megathrust earthquakes. Constraints on slow slip can help us constrain how the earthquake-generating region is loaded to failure. Slow slip may even help us understand how large earthquakes start, as the physics governing the beginning of slow slip is likely the same physics that governs the beginning of large earthquakes.
Slow slip is also important because it is abundant. M>6 events have been observed on most well-instrumented subduction zones, accommodating large fractions of the plate interface slip at depth. If we are to understand the seismic cycle and the stress state at subduction ones, we need to understand slow slip.
A number of physical mechanisms have been proposed to explain slow slip. And a number of these models have reproduced the slow yet episodic slip, usually by allowing for complications in the fault rheology or spatial variations in the fault properties. However, these models have not appeared capable of reproducing all the properties of observed slow slip events. Specifically, the models are designed to be slow and relatively stable, so they struggle to reproduce the complexity that is increasingly observed within a slow slip event. It thus seems that we need a new or modified model. The challenge is that there are many plausible models to consider. So in this project, I propose to evaluate several models and to identify several model properties that are essential to reproducing observed slow slip.
To better evaluate these models, I propose to compare them with existing observations of large slow slip events as well as new analysis of data from the more numerous small slow slip events in central Cascadia. Several tens of small slow slip events occur annually in Cascadia. They are accompanied by seismic tremor: low-amplitude, sustained seismic vibrations thought to be composed of numerous tiny earthquakes driven by the slow slip event. We will track the tremor locations, so that we can see how the small slow slip events grow in space. In addition, we will estimate the magnitude of aseismic slip in the small events, using the unique network of high-precision PBO borehole strainmeters in Cascadia. We will use these new analyses to evaluate several numerical models of slow slip and constrain essential model characteristics.
Episodic slow slip is important to understand because slow slip events occur just below the locked zone, which hosts hazardous megathrust earthquakes. Constraints on slow slip can help us constrain how the earthquake-generating region is loaded to failure. Slow slip may even help us understand how large earthquakes start, as the physics governing the beginning of slow slip is likely the same physics that governs the beginning of large earthquakes.
Slow slip is also important because it is abundant. M>6 events have been observed on most well-instrumented subduction zones, accommodating large fractions of the plate interface slip at depth. If we are to understand the seismic cycle and the stress state at subduction ones, we need to understand slow slip.
A number of physical mechanisms have been proposed to explain slow slip. And a number of these models have reproduced the slow yet episodic slip, usually by allowing for complications in the fault rheology or spatial variations in the fault properties. However, these models have not appeared capable of reproducing all the properties of observed slow slip events. Specifically, the models are designed to be slow and relatively stable, so they struggle to reproduce the complexity that is increasingly observed within a slow slip event. It thus seems that we need a new or modified model. The challenge is that there are many plausible models to consider. So in this project, I propose to evaluate several models and to identify several model properties that are essential to reproducing observed slow slip.
To better evaluate these models, I propose to compare them with existing observations of large slow slip events as well as new analysis of data from the more numerous small slow slip events in central Cascadia. Several tens of small slow slip events occur annually in Cascadia. They are accompanied by seismic tremor: low-amplitude, sustained seismic vibrations thought to be composed of numerous tiny earthquakes driven by the slow slip event. We will track the tremor locations, so that we can see how the small slow slip events grow in space. In addition, we will estimate the magnitude of aseismic slip in the small events, using the unique network of high-precision PBO borehole strainmeters in Cascadia. We will use these new analyses to evaluate several numerical models of slow slip and constrain essential model characteristics.
Planned Impact
With the proposed research, we seek to understand how slow slip events work. Slow slip events are an important part of the seismic cycle at subduction zones, which includes hazardous M 8-9 megathrust earthquakes. Slow slip events often occur just down-dip of the zone that generates major earthquakes. That means that each slow slip event increases the stress in the seismogenic zone. That stress has the potential to trigger large earthquakes. It may even be that large earthquakes begin as slow slip events, and that some slow slip events eventually grow and become seismogenic, rupturing up to the trench. In this case, we should be examining properties of slow slip events to see if we can decipher some characteristics that determine the eventual behaviour.
On the other hand, we should also accept that slow slip events may not be useful for predicting large earthquakes. For instance, in Cascadia the stress at the lower limit of the seismogenic zone likely does accumulate mostly during slow slip events, so it seems most likely that the next earthquake will start during a slow slip event. However, there are several hundred slow slip events between megathrust earthquakes, each one lasting several weeks, so the knowledge of the small increase in stress may not be useful in mitigating the time-dependent risks associated with earthquakes at subduction zones---unless there happens to be some property of slow slip events that reveals the current stress regime.
The time-independent risks associated with the slow slip region may be a more useful line of investigation. An important question is whether megathrust earthquakes can rupture into the slow slip region. The slow slip region is located farther inland that the locked zone. That means it is closer to and sometimes directly under large cities. If the slow slip region ruptures in an earthquake, the shaking in these highly populated area could be much larger than if only the locked region regions. Whether or not the slow slip region ruptures in current models depends on which model you use---especially on whether the model is inherently stable and on what stresses exist on the plate interface. If we are to usefully predict whether or not the slow slip region will rupture seismically, we need to know which model we should be using.
To summarise, we currently do not know whether slow slip events pose or tell us about the hazard introduced by earthquakes. Since we often observe only the largest slow slip events, it is not practical to apply hazard analysis techniques in an empirical, statistical sense. It would seem that if we are to effectively use slow slip in hazard analysis, we need to understand what causes it.
Given the current state of slow slip understanding, the knowledge gained here will be initially most useful to the regional geologic surveys---in this case, the Canadian Geological Survey and the United States Geological Survey. As we make progress in understanding what slow slip tells us about earthquake hazard, the information will likely be first applied in estimating the risk in well-instrumented regions, such as the US, Japan, New Zealand, and Costa Rica. Scientists working on earthquake hazard quantification---from the geological surveys and academic institutions---routinely attend conferences and workshops. The most effective communication is likely through the normal academic channels: formal and informal discussions and published papers.
On the other hand, we should also accept that slow slip events may not be useful for predicting large earthquakes. For instance, in Cascadia the stress at the lower limit of the seismogenic zone likely does accumulate mostly during slow slip events, so it seems most likely that the next earthquake will start during a slow slip event. However, there are several hundred slow slip events between megathrust earthquakes, each one lasting several weeks, so the knowledge of the small increase in stress may not be useful in mitigating the time-dependent risks associated with earthquakes at subduction zones---unless there happens to be some property of slow slip events that reveals the current stress regime.
The time-independent risks associated with the slow slip region may be a more useful line of investigation. An important question is whether megathrust earthquakes can rupture into the slow slip region. The slow slip region is located farther inland that the locked zone. That means it is closer to and sometimes directly under large cities. If the slow slip region ruptures in an earthquake, the shaking in these highly populated area could be much larger than if only the locked region regions. Whether or not the slow slip region ruptures in current models depends on which model you use---especially on whether the model is inherently stable and on what stresses exist on the plate interface. If we are to usefully predict whether or not the slow slip region will rupture seismically, we need to know which model we should be using.
To summarise, we currently do not know whether slow slip events pose or tell us about the hazard introduced by earthquakes. Since we often observe only the largest slow slip events, it is not practical to apply hazard analysis techniques in an empirical, statistical sense. It would seem that if we are to effectively use slow slip in hazard analysis, we need to understand what causes it.
Given the current state of slow slip understanding, the knowledge gained here will be initially most useful to the regional geologic surveys---in this case, the Canadian Geological Survey and the United States Geological Survey. As we make progress in understanding what slow slip tells us about earthquake hazard, the information will likely be first applied in estimating the risk in well-instrumented regions, such as the US, Japan, New Zealand, and Costa Rica. Scientists working on earthquake hazard quantification---from the geological surveys and academic institutions---routinely attend conferences and workshops. The most effective communication is likely through the normal academic channels: formal and informal discussions and published papers.
Organisations
People |
ORCID iD |
| Jessica Hawthorne (Principal Investigator) |
Publications
Gombert B
(2023)
Rapid Tremor Migration During Few Minute-Long Slow Earthquakes in Cascadia
in Journal of Geophysical Research: Solid Earth
Hawthorne J
(2018)
Observing and Modeling the Spectrum of a Slow Slip Event
in Journal of Geophysical Research: Solid Earth
Huang H
(2022)
Linking the scaling of tremor and slow slip near Parkfield, CA.
in Nature communications
| Description | In the first part of this project (and along with other funding), we have examined how much the slip rate in slow slip events varies on timescales from hours to weeks, using data from GPS, strain, and seismic data. Our results provide tentative evidence that slow slip events are composites of numerous smaller slip events. The quantified variability tells us how many subevents of each size there should be and gives us an improved hypothesis for how we should incorporate heterogeneity in models of fault slip. We have further developed the tremor detection technique and used it to analyse the rupture of 4 slow slip events in Cascadia. We have been able to track the slipping region in these events as it moves along the subduction interface at 10 km/day, and we have been able to see a number of sub-ruptures. In particular, we have seen some ruptures that move several km over the course of just 5 minutes. Such ruptures have never been seen before, and their existence will place an additional constraint on which physical processes create slow slip. We then expanded our search for tremor in additional locations, particularly Costa Rica, with the same technique, to assess whether the bursts of tremor found in Cascadia are a global phenomenon. We have found a number of bursts of tremor in Costa Rica, with an interesting new approach to the methodology, successfully using local earthquakes to locate tremor. Though we did not have time to fully explore tremor in Costa Rica. We have, however, further explored a number of tremor bursts in Cascadia. Currently we are using a modified version of our methodology to estimate the seismic energy in each burst, and we have the code and data all set up to estimate the aseismic (slow) energy in each burst. By examining the variation in seismic and aseismic energy, we have been able to determine why small slow earthquakes are faster: are they composed of lots of small seismic events? By examining the aseismic deformation during these events, we have shown that the moment rate is comparable to the moment rate in shorter and longer slow earthquakes, providing further evidence that a single process creates all the slow events. In addition, we have examined the modulation of tremor by atmospheric pressure variations, which present a load on the Earth that clamps and unclamps faults at depth. Our results so far imply that slow slip and tremor diminish during times of clamping. That result is important because it helps distinguish between the proposed models of slow slip. Some models, such as those that invoke viscous shear, predict that there should be no response to clamping stresses. These data suggest that we should explore shear-induced dilatancy or other frictional models as the most likely mechanism to explain slow earthquakes. Finally, we have been modelling our observations. In particular, we are exploring a granular mechanics model that allows slow and fast slip events. We seek to determine whether it can produce the range of slip events that we observe. We have been able to identify a range of slip speeds and understand some of the processes that control those slip speeds. |
| Exploitation Route | If the model we have developed is correct, and slow slip is composed of numerous subevents, the observations will provide important constraints on the physical mechanism that generates slow slip events, and others are likely to use these observations and our understanding to test their models. In addition, if the model proves to be correct, coupling it with other observations will likely indicate that material properties of the fault control slip behaviour---more so than random stress variations. A demonstrated role for material heterogeneity could be taken forward into future estimates of seismic hazard. Our new observations of bursts of propagating tremor and atmospheric modulation will also provide useful constraints on how slow slip works. These results, if fully validated, would argue for shear-induced dilatancy as the dominant mechanism controlling slow slip. The community could, within a few years, be in a position to confidently use a particular model to understand observations of slow slip. We could, for instance, infer properties of the plate interface and use those properties to make predictions about what type of slip that each location should host. Finally, our improved tremor analysis techniques will be useful for other seismologists in detecting small complex signals. The new Costa Rica analysis suggests that we can use local earthquakes as templates to find tremor, and that ability could prove very useful for future researchers looking for seismic signals that we don't have templates for. |
| Sectors | Energy,Environment |