Free Standard AU & NZ Shipping For All Book Orders Over $80!
Register      Login
ASEG Extended Abstracts ASEG Extended Abstracts Society
ASEG Extended Abstracts
RESEARCH ARTICLE

Advanced concepts in active and passive seismic monitoring using full wavefield techniques

David Lumley and Jeffrey Shragge

ASEG Extended Abstracts 2013(1) 1 - 4
Published: 12 August 2013

Abstract

Time-lapse seismic monitoring of reservoir fluid flow and other time-variant subsurface phenomena can be achieved with active and/or passive source seismology. Conventionally, active-source 4D seismic monitoring of reservoir production changes in saturation, pressure, and geomechanical effects is conventionally done via prestack time migration analysis of the time-lapse wavefields. Instead, we present new developments that demonstrate the benefits of using the full time-lapse wavefields more accurately, for example via 4D prestack depth migration (4D PSDM), 4D wave-equation migration velocity analysis (4D WEMVA) and 4D full waveform inversion (4D FWI). These new developments provide an opportunity for more accurate imaging of complex scattered 4D wavefields, and also the possibility to monitor very weak signals using 4D coda waves such as in gas depletion reservoirs. Passive-source monitoring of induced seismicity in the subsurface typically involves seismic data recorded from a few sparse sensor locations, picked event arrival times, and triangulation to determine microseismic event source locations. This conventional approach to passive seismic monitoring has remained relatively unchanged for the past 100 years. Instead, we present new developments that demonstrate an opportunity for significant improvements in passive seismic imaging and monitoring by using dense (possibly permanent) buried receiver arrays that record the full induced seismicity wavefields, and by using full wavefield imaging techniques applied to passive array seismic data and scattered noise fields. *possible keynote talk

https://doi.org/10.1071/ASEG2013ab167

© ASEG 2013

PDF (486 KB) Export Citation

Share

Share on Facebook Share on Twitter Share on LinkedIn Share via Email

View Dimensions