Multi-scale 3D characterisation of porosity and organic matter in shales with variable TOC content and thermal maturity: Examples from the Lublin and Baltic Basins, Poland and Lithuania

Understanding the distribution of pores and organic matter with varying organic matter concentrations and maturity is essential to understanding fluid flow in shale systems. Analysis of samples with low, medium, and high total organic carbon (TOC) and varying maturities (gas-mature and oil-mature) e...

Full description

Saved in:
Bibliographic Details
Published in:International journal of coal geology 2017-07, Vol.180, p.100-112
Main Authors: Ma, Lin, Taylor, Kevin G., Dowey, Patrick J., Courtois, Loic, Gholinia, Ali, Lee, Peter D.
Format: Article
Language:English
Subjects:
FIB-SEM
Maturity
Organic matter geometry
Organic matter network
Pore distribution
Pore types
TOC
X-ray tomography
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Understanding the distribution of pores and organic matter with varying organic matter concentrations and maturity is essential to understanding fluid flow in shale systems. Analysis of samples with low, medium, and high total organic carbon (TOC) and varying maturities (gas-mature and oil-mature) enables the impact of both organic matter concentrations and thermal maturation on organic matter porosity to be examined. Three gas-mature samples of varying TOC (Lublin Basin) and one oil-mature sample (Baltic Basin), both with similar mineral compositions, were selected from the same formation. Samples were imaged in 3D over four orders of magnitudes (pixel sizes from 44μm to 5nm). A combination of X-ray computed tomography (XCT) and Focus Ion Beam Scanning Electron Microscopy (FIB-SEM) enabled the morphologic and topological characteristics of minerals, organic matter and pores to be imaged and quantified. In the studied samples, organic matter primarily has two geometries: lamellar masses (length: 1–100μm, thickness: 0.5–2.0μm) and discrete spheroidal particles (0.5–20.0μm). Organic matter forms an inter-connected network where it exceeds a concentration between 6 and 18wt%. Different pore types have different diameters and total pore volumes: inter-mineral pores (0.2μm, 10–94%), organic interface pores (0.2μm, 2–77%), intra-organic pores (0.05μm, 1–40%) and intra-mineral pores (0.05μm diameter, 1–2% of total porosity). The major pore system in the studied shales is composed of inter-mineral pores which occur between clay mineral grains. TOC concentration influences the total volume of organic matter-related pores while maturity controls the presence of intra-organic pores. The study improves the understanding of the relationship of organic matter concentrations, maturity and pore systems in shales. This study characterises porosity and organic matter distributions in 3D; it also improves the understanding of the relationship of organic matter concentrations, maturity and pore systems in shales. •Multi-scale 3D imaging over 4 orders of magnitude (44μm to 5nm)•3D imaging and quantification of organic matter and porosity distributions•Organic matter geometry and concentration control organic matter connectivity•Clay mineral content controls inter-mineral porosity, which is the main pore system.•Maturity controls intra-organic porosity.
ISSN:0166-5162
1872-7840
DOI:10.1016/j.coal.2017.08.002