Bayesian source inversion of microseismic events

Rapid stress release at the source of an earthquake produces seismic waves. Observations of the particle motions from such waves are used in source inversion to characterise the dynamic behaviour of the source and to help in understanding the driving processes. Earthquakes either occur naturally, su...

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Bibliographic Details
Main Author:	Pugh, David James
Other Authors:	White, Robert S., Christie, Philip A.F.
Format:	Doctoral or Postdoctoral Thesis
Language:	English
Published:	University of Cambridge 2016
Subjects:	Seismology Source Inversion Microseismicity Bayesian Methods Research Subject Categories::NATURAL SCIENCES Geophysics Earth Sciences Askja Krafla Iceland
Online Access:	https://www.repository.cam.ac.uk/handle/1810/253751 https://doi.org/10.17863/CAM.15958

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spelling	ftunivcam:oai:www.repository.cam.ac.uk:1810/253751 2023-05-15T16:53:11+02:00 Bayesian source inversion of microseismic events Pugh, David James White, Robert S. Christie, Philip A.F. 2016-01-05 https://www.repository.cam.ac.uk/handle/1810/253751 https://doi.org/10.17863/CAM.15958 en eng University of Cambridge Department of Earth Sciences Emmanuel College https://www.repository.cam.ac.uk/handle/1810/253751 doi:10.17863/CAM.15958 Seismology Source Inversion Microseismicity Bayesian Methods Research Subject Categories::NATURAL SCIENCES Geophysics Earth Sciences Thesis Doctoral Doctor of Philosophy (PhD) 2016 ftunivcam https://doi.org/10.17863/CAM.15958 2019-02-07T23:17:52Z Rapid stress release at the source of an earthquake produces seismic waves. Observations of the particle motions from such waves are used in source inversion to characterise the dynamic behaviour of the source and to help in understanding the driving processes. Earthquakes either occur naturally, such as in volcanic eruptions and natural geothermal fields, or are linked to anthropogenic activities including hydrofracture of gas and oil reservoirs, mining events and extraction of geothermal fluids. Source inversion is very sensitive to uncertainties in both the model and the data, especially for low magnitude, namely microseismic, events. Many of the uncertainties can be poorly quantified, and are often not included in source inversion. This thesis proposes a Bayesian framework enabling a complete inclusion of uncertainties in the resultant probability distribution using Bayesian marginalisation. This approach is developed for polarity and amplitude ratio data, although it is possible to use any data type, provided the noise model can be estimated. The resultant posterior probability distributions are easily visualised on different plots for orientation and source-type. Several different algorithms can be used to search the source space, including Monte Carlo random sampling and Markov chain Monte Carlo sampling. Relative information between co-located events may be used as an extension to the framework, improving the constraint on the source. The double-couple source is the commonly assumed source model for many earthquakes, corresponding to slip on a fault plane. Two methods for estimating the posterior model probability of the double-couple source type are explored, one using the Bayesian evidence, the other using trans-dimensional Markov chain Monte Carlo sampling. Results from both methods are consistent with each other, producing good estimates of the probability given sufficient samples. These provide estimates of the probability of the source being a double-couple source or not, which is very useful when trying to understand the processes causing the earthquake. Uncertainty on the polarity estimation is often hard to characterise, so an alternative approach for determining the polarity and its associated uncertainty is proposed. This uses a Bayesian estimate of the polarity probability and includes both the background noise and the arrival time pick uncertainty, resulting in a more quantitative estimate of the polarity uncertainty. Moreover, this automated approach can easily be included in automatic event detection and location workflows. The inversion approach is discussed in detail and then applied to both synthetic events generated using a finite-difference code, and to real events acquired from a temporary seismometer network deployed around the Askja and Krafla Volcanoes, Iceland. Acknowledgements: This work was undertaken through a UK Natural Environment Research Council CASE studentship (NE/I018263/1) in partnership with Schlumberger Gould Research. Doctoral or Postdoctoral Thesis Iceland Apollo - University of Cambridge Repository Askja ENVELOPE(-16.802,-16.802,65.042,65.042) Krafla ENVELOPE(-16.747,-16.747,65.713,65.713)
institution	Open Polar
collection	Apollo - University of Cambridge Repository
op_collection_id	ftunivcam
language	English
topic	Seismology Source Inversion Microseismicity Bayesian Methods Research Subject Categories::NATURAL SCIENCES Geophysics Earth Sciences
spellingShingle	Seismology Source Inversion Microseismicity Bayesian Methods Research Subject Categories::NATURAL SCIENCES Geophysics Earth Sciences Pugh, David James Bayesian source inversion of microseismic events
topic_facet	Seismology Source Inversion Microseismicity Bayesian Methods Research Subject Categories::NATURAL SCIENCES Geophysics Earth Sciences
description	Rapid stress release at the source of an earthquake produces seismic waves. Observations of the particle motions from such waves are used in source inversion to characterise the dynamic behaviour of the source and to help in understanding the driving processes. Earthquakes either occur naturally, such as in volcanic eruptions and natural geothermal fields, or are linked to anthropogenic activities including hydrofracture of gas and oil reservoirs, mining events and extraction of geothermal fluids. Source inversion is very sensitive to uncertainties in both the model and the data, especially for low magnitude, namely microseismic, events. Many of the uncertainties can be poorly quantified, and are often not included in source inversion. This thesis proposes a Bayesian framework enabling a complete inclusion of uncertainties in the resultant probability distribution using Bayesian marginalisation. This approach is developed for polarity and amplitude ratio data, although it is possible to use any data type, provided the noise model can be estimated. The resultant posterior probability distributions are easily visualised on different plots for orientation and source-type. Several different algorithms can be used to search the source space, including Monte Carlo random sampling and Markov chain Monte Carlo sampling. Relative information between co-located events may be used as an extension to the framework, improving the constraint on the source. The double-couple source is the commonly assumed source model for many earthquakes, corresponding to slip on a fault plane. Two methods for estimating the posterior model probability of the double-couple source type are explored, one using the Bayesian evidence, the other using trans-dimensional Markov chain Monte Carlo sampling. Results from both methods are consistent with each other, producing good estimates of the probability given sufficient samples. These provide estimates of the probability of the source being a double-couple source or not, which is very useful when trying to understand the processes causing the earthquake. Uncertainty on the polarity estimation is often hard to characterise, so an alternative approach for determining the polarity and its associated uncertainty is proposed. This uses a Bayesian estimate of the polarity probability and includes both the background noise and the arrival time pick uncertainty, resulting in a more quantitative estimate of the polarity uncertainty. Moreover, this automated approach can easily be included in automatic event detection and location workflows. The inversion approach is discussed in detail and then applied to both synthetic events generated using a finite-difference code, and to real events acquired from a temporary seismometer network deployed around the Askja and Krafla Volcanoes, Iceland. Acknowledgements: This work was undertaken through a UK Natural Environment Research Council CASE studentship (NE/I018263/1) in partnership with Schlumberger Gould Research.
author2	White, Robert S. Christie, Philip A.F.
format	Doctoral or Postdoctoral Thesis
author	Pugh, David James
author_facet	Pugh, David James
author_sort	Pugh, David James
title	Bayesian source inversion of microseismic events
title_short	Bayesian source inversion of microseismic events
title_full	Bayesian source inversion of microseismic events
title_fullStr	Bayesian source inversion of microseismic events
title_full_unstemmed	Bayesian source inversion of microseismic events
title_sort	bayesian source inversion of microseismic events
publisher	University of Cambridge
publishDate	2016
url	https://www.repository.cam.ac.uk/handle/1810/253751 https://doi.org/10.17863/CAM.15958
long_lat	ENVELOPE(-16.802,-16.802,65.042,65.042) ENVELOPE(-16.747,-16.747,65.713,65.713)
geographic	Askja Krafla
geographic_facet	Askja Krafla
genre	Iceland
genre_facet	Iceland
op_relation	https://www.repository.cam.ac.uk/handle/1810/253751 doi:10.17863/CAM.15958
op_doi	https://doi.org/10.17863/CAM.15958
_version_	1766043694436188160

Bayesian source inversion of microseismic events

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