Tomographic image analysis and processing to simulate micro-petrophysical experiments

Date

2010

Authors

Sakellariou, Arthur
Kingston, Andrew
Varslot, Trond
Sheppard, Adrian
Latham, Shane
Sok, Robert
Arns, Christoph
Senden, Timothy
Knackstedt, Mark

Journal Title

Journal ISSN

Volume Title

Publisher

SPIE - The International Society for Optical Engineering

Abstract

We present a description of our departments work flow that utilises X-ray micro-tomography in the observation and prediction of physical properties of porous rock. These properties include fluid flow, dissolution/deposition, fracture mapping, and mechanical processes, as well as measurement of three-dimensional (3D) morphological attributes such as pore/grain size and shape distributions, and pore/grain connectivity. To support all these areas there is a need for well integrated and parallel research programs in hardware development, structural description and physical property modelling. Since we have the ability to validate simulation with physical measurement, (and vice versa), an important part of the integration of all these techniques is calibration at every stage of the work flow. For example, we can use high-resolution scanning electron microscopy (SEM) images to verify or improve our sophisticated segmentation algorithm based on image grey-levels and gradients. The SEM can also be used to obtain sub-resolution porosity information estimated from tomographic grey-levels and texture. Comparing experimental and simulated mercury intrusion porosimetry can quantify the effective resolution of tomograms and the accuracy of segmentation. The foundation of our calibration techniques is a robust and highly optimised 3D to 3D image-based registration method. This enables us to compare the tomograms of successively disturbed (e.g., dissolved, fractured, cleaned,...) specimens with an original undisturbed state. A two-dimensional (2D) to 3D version of this algorithm allows us to register microscope images (both SEM and quantitative electron microscopy) of prepared 2D sections of each specimen. This can assist in giving a multimodal assessment of the specimen.

Description

Keywords

Keywords: 3-D image; 3D image registration; Calibration techniques; Fluid flow; Fracture mapping; Hardware development; High-resolution scanning electron microscopies; Mechanical process; Mercury intrusion porosimetry; Microscope images; Multi-modal; Petrophysical; 3D image registration; petrophysics; Quantitative analysis and modelling; X-ray micro-tomography

Citation

Source

Proceedings of SPIE - Progress in Biomedical Optics and Imaging

Type

Journal article

Book Title

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2037-12-31