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Ultrasonic monitoring of spontaneous imbibition experiments: Acoustic signature of fluid migration
Author(s) -
David Christian,
Barnes Christophe,
Desrues Mathilde,
Pimienta Lucas,
Sarout Joël,
Dautriat Jérémie
Publication year - 2017
Publication title -
journal of geophysical research: solid earth
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.983
H-Index - 232
eISSN - 2169-9356
pISSN - 2169-9313
DOI - 10.1002/2016jb013804
Subject(s) - amplitude , ultrasonic sensor , waveform , geology , imbibition , acoustics , signal (programming language) , wavelet , mechanics , seismology , optics , physics , germination , botany , quantum mechanics , voltage , artificial intelligence , computer science , biology , programming language
Abstract Capillary rise experiments (spontaneous imbibition tests) were conducted in the laboratory with ultrasonic and X‐ray monitoring on the Sherwood sandstone and the Majella grainstone. The aim was to provide a direct comparison between the variation in seismic attributes (amplitude, velocity, spectral content, and energy) and the actual fluid distribution in the rock. Two pairs of ultrasonic P wave sensors located at different heights on a cylindrical rock specimen recorded every 5 s the waveforms when capillary forces make water rise up into the rock from the bottom in contact with a water tank. Simultaneously, computerized tomography scan images of a vertical cross section were also recorded. Two important results were found. (i) The amplitude of the first P wave arrival is impacted by the upward moving fluid front before the P wave velocity is, while the fluid front has not yet reached the sensors level. In contrast, the P wave velocity decreases when the fluid front reaches the Fresnel clearance zone. The spectral analysis of the waveforms shows that the peak frequency amplitude is continuously decreasing without noticeable frequency shift. (ii) A methodology based on the calculation of the analytical signal and instantaneous phase was designed to decompose each waveform into discrete wavelets associated with direct or reflected waves. The energy carried by the wavelets is very sensitive to the fluid substitution process: the coda wavelets related to reflections on the bottom end face of the specimen are impacted as soon as imbibition starts and can be used as a precursor for the arriving fluid.

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