EGU24-11389, updated on 09 Mar 2024
https://doi.org/10.5194/egusphere-egu24-11389
EGU General Assembly 2024
© Author(s) 2024. This work is distributed under
the Creative Commons Attribution 4.0 License.

Adjoint-Source Inversion of Microseismic Sources with DAS in Boreholes

Katinka Tuinstra1, Federica Lanza1, Sebastian Noe2, Andreas Fichtner2, Antonio Pio Rinaldi1, Pascal Edme1,2, Martina Rosskopf2, Anne Obermann1, Marian Hertrich3, Hansruedi Maurer2, Domenico Giardini2, Stefan Wiemer1, and the Bedretto Team*
Katinka Tuinstra et al.
  • 1ETH Zurich, Swiss Seismological Service, Department of Earth Sciences, Zürich, Switzerland (katinka.tuinstra@sed.ethz.ch)
  • 2ETH Zurich, Department of Earth Sciences, Institute of Geophysics, Zurich, Switzerland
  • 3ETH Zurich, Department of Earth Sciences, Zurich, Switzerland
  • *A full list of authors appears at the end of the abstract

Microseismic source processes can be closely monitored during hydraulic stimulations with optical fiber deployed behind borehole casing, using Distributed Acoustic Sensing (DAS). The Bedretto Underground Laboratory for the Geosciences and Geoenergies (BULGG) provides a test site at the scale of hundreds of meters (meso-scale), where multiple boreholes are instrumented with fibers around a stimulation well. This enables the characterization of source properties of induced seismicity thanks to the dense sampling of the wavefield close to the stimulated region.

In 2023 various stimulation activities in the BedrettoLab produced M<-1 events that were recorded on three fibers surrounding the stimulated region. The interrogated fibers are running through the stimulated seismicity zone, and surround the majority of the events. Some of these events are recorded with high coherency and signal-to-noise ratio, making them suitable for further source characterization, such as location and moment tensor inversion. These events were at the same time recorded with other co-located point sensors such as geophones and acoustic emission sensors, which enables comparison to other instruments.

In this work, we select and process a subset of events with clear DAS recordings, and invert for their location, source time and moment tensor components using an adjoint inversion method. This includes computing the full forward and adjoint wavefield and gradient using a spectral-element solver. Using the full waveforms to invert for these events greatly improves the resolution of the source estimates, allows for incorporation of the full velocity model, and only two simulations per iteration are required: a forward and adjoint simulation, and gradient computation. The receiver coverage of the focal spheres by the surrounding optical fibers is an excellent test bed for the method, and the simulated domain remains on the order of hundreds of meters, which means that the simulation can be pushed to high frequencies (>100 Hz). This study provides a step forward to monitoring microseismicity in hydraulic stimulations with fiber-optic measurements.

Bedretto Team:

The team involves more than 30 people from ETHZ as well as 10 research institutes and companies (see http://www.bedrettolab.ethz.ch/en/home/).

How to cite: Tuinstra, K., Lanza, F., Noe, S., Fichtner, A., Rinaldi, A. P., Edme, P., Rosskopf, M., Obermann, A., Hertrich, M., Maurer, H., Giardini, D., and Wiemer, S. and the Bedretto Team: Adjoint-Source Inversion of Microseismic Sources with DAS in Boreholes, EGU General Assembly 2024, Vienna, Austria, 14–19 Apr 2024, EGU24-11389, https://doi.org/10.5194/egusphere-egu24-11389, 2024.