Litcius/Paper detail

Rayleigh-wave multicomponent crosscorrelation-based source strength distribution inversions. Part 2: a workflow for field seismic data

Zongbo Xu, T. Dylan Mikesell, Josefine Umlauft, Gabriel Gribler

2020Geophysical Journal International21 citationsDOIOpen Access PDF

Abstract

SUMMARY Estimation of ambient seismic source distributions (e.g. location and strength) can aid studies of seismic source mechanisms and subsurface structure investigations. One can invert for the ambient seismic (noise) source distribution by applying full-waveform inversion (FWI) theory to seismic (noise) crosscorrelations. This estimation method is especially applicable for seismic recordings without obvious body-wave arrivals. Data pre-processing procedures are needed before the inversion, but some pre-processing procedures commonly used in ambient noise tomography can bias the ambient (noise) source distribution estimation and should not be used in FWI. Taking this into account, we propose a complete workflow from the raw seismic noise recording through pre-processing procedures to the inversion. We present the workflow with a field data example in Hartoušov, Czech Republic, where the seismic sources are CO2 degassing areas at Earth’s surface (i.e. a fumarole or mofette). We discuss factors in the processing and inversion that can bias the estimations, such as inaccurate velocity model, anelasticity and array sensitivity. The proposed workflow can work for multicomponent data across different scales of field data.

Topics & Concepts

Seismic noiseAmbient noise levelInversion (geology)GeologyWorkflowSeismic inversionSpurious relationshipRayleigh waveSeismologyData processingPassive seismicNoise (video)Seismic interferometrySeismic to simulationGeodesyComputer scienceSurface waveMeteorologyInterferometryData assimilationDatabaseTelecommunicationsOpticsTectonicsGeomorphologyMachine learningImage (mathematics)Artificial intelligenceSound (geography)PhysicsSeismic Waves and AnalysisSeismic Imaging and Inversion TechniquesSeismology and Earthquake Studies