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Related Experiment Videos

Permeability relation for periodic structures

K J Dunn1, G A LaTorraca, D J Bergman

  • 1Chevron Petroleum Technology Company, La Habra, CA 90631-6374, USA. jkjdu@chevron.com

Magnetic Resonance Imaging
|November 6, 1998
PubMed
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This study explores the relationship between permeability and other petrophysical parameters in periodic porous media. Findings reveal correlations between permeability, formation factor, porosity, and nuclear magnetic resonance relaxation time.

Area of Science:

  • Geophysics
  • Materials Science
  • Fluid Dynamics

Background:

  • Understanding fluid flow in porous media is crucial for various geoscience and engineering applications.
  • Petrophysical parameters like porosity and formation factor are key descriptors of porous materials.
  • Nuclear Magnetic Resonance (NMR) relaxation time offers insights into pore structure and fluid interactions.

Purpose of the Study:

  • To investigate the permeability relation for periodic porous media.
  • To establish correlations between permeability and other petrophysical parameters.
  • To analyze these relationships in different cubic sphere packing arrangements.

Main Methods:

  • Computed formation factors using a Fourier-space integral equation method.
  • Utilized literature values for permeability in periodic structures (simple, body-centered, face-centered cubic arrays of spheres).

Related Experiment Videos

  • Investigated correlation schemes relating permeability to NMR relaxation time, porosity, and formation factor.
  • Main Results:

    • Established correlations between permeability (k) and formation factor (F), porosity (phi), and NMR relaxation time (T).
    • Explored functional relationships of the form k = aTbFc and k = aTb phi c.
    • Demonstrated the utility of NMR relaxation time as a predictor of permeability.

    Conclusions:

    • Permeability in periodic porous media is strongly related to formation factor, porosity, and NMR relaxation time.
    • The established correlations provide a basis for estimating permeability from other measurable petrophysical properties.
    • This research contributes to a better understanding of fluid transport in engineered and natural porous systems.