Estimating the Occurrence of Slow Slip Events and Earthquakes with an Ensemble Kalman Filter

Hamed Ali Diab Montero; Meng Li; Ylona van Dinther; Femke Vossepoel

doi:10.1093/gji/ggad154

Estimating the Occurrence of Slow Slip Events and Earthquakes with an Ensemble Kalman Filter

Hamed Ali Diab Montero^*, Meng Li, Ylona van Dinther, Femke Vossepoel

^*Corresponding author for this work

Delft University of Technology

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Our ability to forecast earthquakes and slow slip events is hampered by limited information on the current state of stress on faults. Ensemble data assimilation methods permit estimating the state by combining physics-based models and observations, while considering their uncertainties. We use an ensemble Kalman filter (EnKF) to estimate shear stresses, slip rates and the state θ acting on a fault point governed by rate-and-state friction embedded in a 1-D elastic medium. We test the effectiveness of data assimilation by conducting perfect model experiments. We assimilate noised shear-stress and velocity synthetic values acquired at a small distance to the fault. The assimilation of uncertain shear stress observations improves in particular the estimates of shear stress on fault segments hosting slow slip events, while assimilating observations of velocity improves their slip-rate estimation. Both types of observations help equally well to better estimate the state θ. For earthquakes, the shear stress observations improve the estimation of shear stress, slip rates and the state θ, whereas the velocity observations improve in particular the slip-rate estimation. Data assimilation significantly improves the estimates of the temporal occurrence of slow slip events and to a large extent also of earthquakes. Rapid and abrupt changes in velocity and shear stress during earthquakes lead to non-Gaussian priors for subsequent assimilation steps, which breaks the assumption of Gaussian priors of the EnKF. In spite of this, the EnKF still provides estimates that are unexpectedly close to the true evolution. In fact, the forecastability for earthquakes for the same alarm duration is very similar to slow slip events, having a very low miss rate with an alarm duration of just 10 per cent of the recurrence interval of the events. These results confirm that data assimilation is a promising approach for the combination of uncertain physics and indirect, noisy observations for the forecasting of both slow slip events and earthquakes.

Original language	English
Pages (from-to)	1701-1721
Number of pages	21
Journal	Geophysical Journal International
Volume	234
Issue number	3
DOIs	https://doi.org/10.1093/gji/ggad154
Publication status	Published - 3 Sept 2023

Bibliographical note

Funding Information:
This publication is part of the ‘InFocus: An Integrated Approach to Estimating Fault Slip Occurrence’ project (grant number: DEEP.NL.2018.037) funded by NWO’s (Dutch Research Council) DeepNL programme, which aims to improve the fundamental understanding of the dynamics of the deep subsurface under the influence of human interventions. Additionally, the authors thank Casper Pranger who developed the code library Garnet, and also Lars Nerger and the Alfred Wegener Institute for Polar and Marine Research(AWI) team for the code library Parallel Data Assimilation Framework (PDAF). HDM thanks Simone Spada and Andreas Stordal, who helped to improve this paper with fruitful discussions. We thank the reviewers, Masayuki Kano and Takane Hori, for giving valuable suggestions for improvement.

Funding Information:
This publication is part of the ‘InFocus: An Integrated Approach to Estimating Fault Slip Occurrence’ project (grant number: DEEP.NL.2018.037) funded by NWO’s (Dutch Research Council) DeepNL programme, which aims to improve the fundamental understanding of the dynamics of the deep subsurface under the influence of human interventions. Additionally, the authors thank Casper Pranger who developed the code library Garnet, and also Lars Nerger and the Alfred Wegener Institute for Polar and Marine Research(AWI) team for the code library Parallel Data Assimilation Framework (PDAF). HDM thanks Simone Spada and Andreas Stordal, who helped to improve this paper with fruitful discussions. We thank the reviewers, Masayuki Kano and Takane Hori, for giving valuable suggestions for improvement.

Publisher Copyright:
© The Author(s) 2023. Published by Oxford University Press on behalf of The Royal Astronomical Society.

Keywords

Seismic cycle; Inverse theory; Numerical modelling; Probabilistic forecasting; Earthquake interaction
forecasting
prediction; Earthquake dynamics; Data assimilation; Ensemble Kalman filter

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10.1093/gji/ggad154Licence: CC BY

ggad154Final published version, 11.7 MBLicence: CC BY

Cite this

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title = "Estimating the Occurrence of Slow Slip Events and Earthquakes with an Ensemble Kalman Filter",

abstract = "Our ability to forecast earthquakes and slow slip events is hampered by limited information on the current state of stress on faults. Ensemble data assimilation methods permit estimating the state by combining physics-based models and observations, while considering their uncertainties. We use an ensemble Kalman filter (EnKF) to estimate shear stresses, slip rates and the state θ acting on a fault point governed by rate-and-state friction embedded in a 1-D elastic medium. We test the effectiveness of data assimilation by conducting perfect model experiments. We assimilate noised shear-stress and velocity synthetic values acquired at a small distance to the fault. The assimilation of uncertain shear stress observations improves in particular the estimates of shear stress on fault segments hosting slow slip events, while assimilating observations of velocity improves their slip-rate estimation. Both types of observations help equally well to better estimate the state θ. For earthquakes, the shear stress observations improve the estimation of shear stress, slip rates and the state θ, whereas the velocity observations improve in particular the slip-rate estimation. Data assimilation significantly improves the estimates of the temporal occurrence of slow slip events and to a large extent also of earthquakes. Rapid and abrupt changes in velocity and shear stress during earthquakes lead to non-Gaussian priors for subsequent assimilation steps, which breaks the assumption of Gaussian priors of the EnKF. In spite of this, the EnKF still provides estimates that are unexpectedly close to the true evolution. In fact, the forecastability for earthquakes for the same alarm duration is very similar to slow slip events, having a very low miss rate with an alarm duration of just 10 per cent of the recurrence interval of the events. These results confirm that data assimilation is a promising approach for the combination of uncertain physics and indirect, noisy observations for the forecasting of both slow slip events and earthquakes.",

keywords = "Seismic cycle; Inverse theory; Numerical modelling; Probabilistic forecasting; Earthquake interaction, forecasting, prediction; Earthquake dynamics; Data assimilation; Ensemble Kalman filter",

author = "{Diab Montero}, {Hamed Ali} and Meng Li and {van Dinther}, Ylona and Femke Vossepoel",

note = "Funding Information: This publication is part of the {\textquoteleft}InFocus: An Integrated Approach to Estimating Fault Slip Occurrence{\textquoteright} project (grant number: DEEP.NL.2018.037) funded by NWO{\textquoteright}s (Dutch Research Council) DeepNL programme, which aims to improve the fundamental understanding of the dynamics of the deep subsurface under the influence of human interventions. Additionally, the authors thank Casper Pranger who developed the code library Garnet, and also Lars Nerger and the Alfred Wegener Institute for Polar and Marine Research(AWI) team for the code library Parallel Data Assimilation Framework (PDAF). HDM thanks Simone Spada and Andreas Stordal, who helped to improve this paper with fruitful discussions. We thank the reviewers, Masayuki Kano and Takane Hori, for giving valuable suggestions for improvement. Funding Information: This publication is part of the {\textquoteleft}InFocus: An Integrated Approach to Estimating Fault Slip Occurrence{\textquoteright} project (grant number: DEEP.NL.2018.037) funded by NWO{\textquoteright}s (Dutch Research Council) DeepNL programme, which aims to improve the fundamental understanding of the dynamics of the deep subsurface under the influence of human interventions. Additionally, the authors thank Casper Pranger who developed the code library Garnet, and also Lars Nerger and the Alfred Wegener Institute for Polar and Marine Research(AWI) team for the code library Parallel Data Assimilation Framework (PDAF). HDM thanks Simone Spada and Andreas Stordal, who helped to improve this paper with fruitful discussions. We thank the reviewers, Masayuki Kano and Takane Hori, for giving valuable suggestions for improvement. Publisher Copyright: {\textcopyright} The Author(s) 2023. Published by Oxford University Press on behalf of The Royal Astronomical Society.",

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doi = "10.1093/gji/ggad154",

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N2 - Our ability to forecast earthquakes and slow slip events is hampered by limited information on the current state of stress on faults. Ensemble data assimilation methods permit estimating the state by combining physics-based models and observations, while considering their uncertainties. We use an ensemble Kalman filter (EnKF) to estimate shear stresses, slip rates and the state θ acting on a fault point governed by rate-and-state friction embedded in a 1-D elastic medium. We test the effectiveness of data assimilation by conducting perfect model experiments. We assimilate noised shear-stress and velocity synthetic values acquired at a small distance to the fault. The assimilation of uncertain shear stress observations improves in particular the estimates of shear stress on fault segments hosting slow slip events, while assimilating observations of velocity improves their slip-rate estimation. Both types of observations help equally well to better estimate the state θ. For earthquakes, the shear stress observations improve the estimation of shear stress, slip rates and the state θ, whereas the velocity observations improve in particular the slip-rate estimation. Data assimilation significantly improves the estimates of the temporal occurrence of slow slip events and to a large extent also of earthquakes. Rapid and abrupt changes in velocity and shear stress during earthquakes lead to non-Gaussian priors for subsequent assimilation steps, which breaks the assumption of Gaussian priors of the EnKF. In spite of this, the EnKF still provides estimates that are unexpectedly close to the true evolution. In fact, the forecastability for earthquakes for the same alarm duration is very similar to slow slip events, having a very low miss rate with an alarm duration of just 10 per cent of the recurrence interval of the events. These results confirm that data assimilation is a promising approach for the combination of uncertain physics and indirect, noisy observations for the forecasting of both slow slip events and earthquakes.

AB - Our ability to forecast earthquakes and slow slip events is hampered by limited information on the current state of stress on faults. Ensemble data assimilation methods permit estimating the state by combining physics-based models and observations, while considering their uncertainties. We use an ensemble Kalman filter (EnKF) to estimate shear stresses, slip rates and the state θ acting on a fault point governed by rate-and-state friction embedded in a 1-D elastic medium. We test the effectiveness of data assimilation by conducting perfect model experiments. We assimilate noised shear-stress and velocity synthetic values acquired at a small distance to the fault. The assimilation of uncertain shear stress observations improves in particular the estimates of shear stress on fault segments hosting slow slip events, while assimilating observations of velocity improves their slip-rate estimation. Both types of observations help equally well to better estimate the state θ. For earthquakes, the shear stress observations improve the estimation of shear stress, slip rates and the state θ, whereas the velocity observations improve in particular the slip-rate estimation. Data assimilation significantly improves the estimates of the temporal occurrence of slow slip events and to a large extent also of earthquakes. Rapid and abrupt changes in velocity and shear stress during earthquakes lead to non-Gaussian priors for subsequent assimilation steps, which breaks the assumption of Gaussian priors of the EnKF. In spite of this, the EnKF still provides estimates that are unexpectedly close to the true evolution. In fact, the forecastability for earthquakes for the same alarm duration is very similar to slow slip events, having a very low miss rate with an alarm duration of just 10 per cent of the recurrence interval of the events. These results confirm that data assimilation is a promising approach for the combination of uncertain physics and indirect, noisy observations for the forecasting of both slow slip events and earthquakes.

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Estimating the Occurrence of Slow Slip Events and Earthquakes with an Ensemble Kalman Filter

Abstract

Bibliographical note

Keywords

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