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Unsymmetric compressibility matrix to model P-wave attenuation

Unsymmetric compressibility matrix to model P-wave attenuation In double permeability models, the first and second porosities are represented by the main pores and fissures, respectively. The constitutional relation in the models suffers from a disadvantage that the compressibility matrix is symmetric which is incompatible with classic poroelasticity. This study aims to improving the double permeability models not only to well predict the measured velocity and attenuation at ultrasonic frequency, but also to yield the classic Gassmann velocity at the low frequency limit. The first porosity in this paper refers to the main pore space, while the second porosity refers to throat (between grains) and fissures. Our improvements in this paper include: (1) the compressibility matrix is unsymmetric for the model to automatically yield Gassmann velocity at the low frequency limit; (2) squirt coefficient is got from dimensional analysis; and (3) the compressibility coefficients are qualitatively constrained based on rock physics. For simplicity, permeabilities of the first and second porosities are set to zero because local squirt between them is dominant in P-wave attenuation. The wavenumber equation yields one fast P-wave and one slow P-wave (which has zero velocity due to vanishing permeabilities). Two core samples (Berea sandstone and Boise sandstone) with the measured data are used for illustration. The results show that the improved model successfully predicts both velocity and the quality factor of ultrasonic P-wave in the two sandstones, being superior to the previous models. http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png "Acta Geodaetica et Geophysica" Springer Journals

Unsymmetric compressibility matrix to model P-wave attenuation

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Publisher
Springer Journals
Copyright
Copyright © Akadémiai Kiadó 2021
ISSN
2213-5812
eISSN
2213-5820
DOI
10.1007/s40328-021-00344-6
Publisher site
See Article on Publisher Site

Abstract

In double permeability models, the first and second porosities are represented by the main pores and fissures, respectively. The constitutional relation in the models suffers from a disadvantage that the compressibility matrix is symmetric which is incompatible with classic poroelasticity. This study aims to improving the double permeability models not only to well predict the measured velocity and attenuation at ultrasonic frequency, but also to yield the classic Gassmann velocity at the low frequency limit. The first porosity in this paper refers to the main pore space, while the second porosity refers to throat (between grains) and fissures. Our improvements in this paper include: (1) the compressibility matrix is unsymmetric for the model to automatically yield Gassmann velocity at the low frequency limit; (2) squirt coefficient is got from dimensional analysis; and (3) the compressibility coefficients are qualitatively constrained based on rock physics. For simplicity, permeabilities of the first and second porosities are set to zero because local squirt between them is dominant in P-wave attenuation. The wavenumber equation yields one fast P-wave and one slow P-wave (which has zero velocity due to vanishing permeabilities). Two core samples (Berea sandstone and Boise sandstone) with the measured data are used for illustration. The results show that the improved model successfully predicts both velocity and the quality factor of ultrasonic P-wave in the two sandstones, being superior to the previous models.

Journal

"Acta Geodaetica et Geophysica"Springer Journals

Published: May 27, 2021

Keywords: Double porosity; P-wave; Squirt; Constitutional relation; Gassmann velocity

References