--> Quantifying Velocity-Geology-Pressure Relationships in Core: The Foundations of a 4-D Seismic Feasibility Study in the Ichthys Gas-Condensate Field, NW Australia
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AAPG ACE 2018

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Quantifying Velocity-Geology-Pressure Relationships in Core: The Foundations of a 4-D Previous HitSeismicNext Hit Feasibility Study in the Ichthys Gas-Condensate Field, NW Australia

Levi J. Knapp1, Tetsuzo Fukunari1, Keita Yoshimatsu1, Ayato Kato1, Masayoshi Suzuki1, Tatsuya Hattori1, Keiichi Furuya2, Ryoichi Matsui2


1Technical Department, Japan Oil, Gas and Metals National Corporation (JOGMEC), Chiba, Chiba, Japan.
2INPEX, Tokyo, Japan.


July 23 - 25, 2018AAPG ACE 2018,

Posted: July 23-25, 2018

Abstract

The effectiveness of 4D (time-lapse) Previous HitseismicNext Hit reservoir monitoring depends on the ability to reliably detect changes in Previous HitseismicNext Hit response due to production-driven changes in fluid saturation and effective pressure. JOGMEC and INPEX have collaborated to test the feasibility of 4D Previous HitseismicNext Hit monitoring in the Ichthys gas-condensate field in the Browse Basin, offshore NW Australia. The foundation of that study, presented here, is an examination of the effects of geological factors and effective pressure (Peff) changes on elastic wave velocity in core plug samples.

P- and S-wave velocities were measured on 55 Brewster Member sandstone core plug samples, at angles of 0°, 45°, and 90° relative to bedding, and under confining pressure of 1000 to 11000 psi. Only hydrostatic pressure conditions will be discussed here. Porosity, permeability, and density were measured on the same plugs, along with X-Ray CT scanning to observe internal fabrics. Plug ends were used to prepare thin sections, with which mineralogy was quantified using QEMSCAN. Quartz cement abundance and grain size statistics were estimated on 40 prioritized samples using a combination of QEMSCAN and cathodoluminescence (CL).

Porosity is the dominant control on velocity, while scatter in the porosity-velocity data is clearly explained by clay content. Velocity measured parallel to bedding is strongly controlled by porosity, while velocity measurements oriented perpendicular to bedding are more sensitive to clays and bedding fabrics. Similarly, pressure sensitivity is consistently higher for velocity measured perpendicular to bedding. Thomsen’s Previous HitanisotropyNext Hit parameters, ε and γ, decrease with increasing effective pressure; ε and γ averaged over all analyzed samples at each pressure step approach zero. Previous HitAnisotropyNext Hit parameter δ, however, shows no relationship to pressure. Functions for geology-velocity, geology-velocity-pressure, and Previous HitanisotropyNext Hit relationships for all wave types and orientations were defined using multiple linear regression.

The results of this core analysis have subsequently been used for rock physics analysis and forward Previous HitseismicNext Hit modeling. The recognition and quantification of Previous HitanisotropyNext Hit in the core analysis has significant implications for subsequent modeling, as higher pressure sensitivity values determined from vertical velocity measurements will yield larger modeled Previous HitseismicTop responses than values determined from horizontal velocity measurements.

AAPG Datapages/Search and Discovery Article #90323 ©2018 AAPG Annual Convention and Exhibition, Salt Lake City, Utah, May 20-23, 2018