Segmented 3D Images of Supercritical CO2-Brine Draiange into Bentheimer Sandstones

In this experiment, we investigated the coupling effect of sub-core-scale heterogeneity and miscibility on the development of flow pattern under drainage in Bentheimer sandstone cores. The multiphase fluid-flow experiments were conducted using the high-temperature, high-pressure (HTHP) tri-axial core flooding system built in-house at the National Laboratory for X-ray Micro Computed Tomography (CTLab), Australian National University. Two sister cores drilled from the same Bentheimer sandstone block were used in this experiment and the porosity profile for the two cores are significantly different with two lower porosity bands being transverse to the direction of flow injection presented in both cores. For the drainage experiments, two series of sub-experiments were performed for each core. In series S ("S" for CO2-saturated), supercritical CO2 (scCO2) was injected into core saturated with CO2-saturated brine to investigate brine displacement by scCO2. After sub-experiment S, unsaturated brine without any dissolved CO2 was flushed through the core to dissolve any trapped scCO2. X-ray fast scans were taken to monitor if all trapped scCO2 was removed, and to ensure the core was reset to fully saturated by unaturated brine. To investigate the coupling of brine displacement by scCO2 and the dissolution of the invading scCO2 into brine, sub-experiment series US (“US” for unsaturated) was performed by injecting scCO2 into the core filled with unsaturated brine. In both the sub-experiments S and US, scCO2 was injected at flow rate equaling 0.01 ml/min, and the corresponding capillary number (Ca) was at the order of 10^-9. Before any fluid flow experiment was conducted, a high-resolution base scan was acquired for core 01 and 02 at voxel size equaling 3.85 and 3.78 micron, respectively. For each of the four sub-experiments (S01, US01, S02, and US02), fast MCT scans were taken simultaneously to track the invasion pattern of scCO2. The resultant voxel size and acquisition time for core 01 (i.e. S01 and US01) equals 15.98 micron and approximately 30 mins, respectively. For core 02, the voxel size was reduced to 13.72 micron by moving the HTHP cell slightly closer to the X-ray source and increasing the voltage for the source. The acquisition time for each fast scans of core 02 (i.e. S02 and US02) were thereby reduced to approximately 16.5 mins. Subsequent image segmentation of the high-resolution dry scan was accomplished via a “Converging Active Contours” (CAC) routine, where the two physical phases, i.e. the air and the grain phase was identified by CAC based on chosen intensity thresholds. For the segmentation of the fast scans acquired during the drainage experiments, each scan was firstly partially segmented as the scCO2 phase and the combined brine and grain phase. The partially segmented fast scans were then overlaid with the segmented high-resolution dry scan for the identification of the brine and the solid phase. Subsequent noise removal of the segmented fast scans including removing scCO2 clusters that were smaller than sphere with radius euqaling 15 micron. In this dataset, data are in .nc format and can be read in ImageJ software via NetCDF plugins (http://www.unidata.ucar.edu/software/netcdf/). Datasets labelled as S0X and US0X were drainage experiments conducted using the same core under immiscible and partially miscible conditions, respectively, with X=1 or 2 labelling experiments conducted with core 01 or 02. Here, the numerals label datasets for each sub-experiments until the breakthrough of scCO2, with datasets in which scCO2 was firstly oberved labelled as 1, e.g. S01_1; "endpoint" labels datasets acquired at the end of each sub-experiment. This dataset contains data acquired until the breakthrough of scCO2 and at the end of each sub-experiment. The remaining datasets are available on request.
Type
collection
Title
Segmented 3D Images of Supercritical CO2-Brine Draiange into Bentheimer Sandstones
Collection Type
Dataset
Access Privileges
Research School of Physics
DOI - Digital Object Identifier
10.25911/58yy-a052
Metadata Language
English
Data Language
English
Brief Description
Segmented 3D images of supercritical CO2-brine drainage experiments into two mildly heterogeneous Bentheimer sandstone cores performed under conditions relevant to geologic carbon sequestration (45 degrees Celsius and 1250 PSI) and under both immiscible and partially miscible conditions. The diameter and height of the cropped sample for the first core ("core 01") was 2581 and 6996 voxels (9.94 and 26.92 mm), respectively, and 2591 and 8889 voxels (9.80 and 33.61 mm) for the second core ("core 02"). The voxel size of these registered data was 3.85 micron and 3.78 micron for core 01 and core 02, respectively.
Full Description
In this experiment, we investigated the coupling effect of sub-core-scale heterogeneity and miscibility on the development of flow pattern under drainage in Bentheimer sandstone cores. The multiphase fluid-flow experiments were conducted using the high-temperature, high-pressure (HTHP) tri-axial core flooding system built in-house at the National Laboratory for X-ray Micro Computed Tomography (CTLab), Australian National University. Two sister cores drilled from the same Bentheimer sandstone block were used in this experiment and the porosity profile for the two cores are significantly different with two lower porosity bands being transverse to the direction of flow injection presented in both cores. For the drainage experiments, two series of sub-experiments were performed for each core. In series S ("S" for CO2-saturated), supercritical CO2 (scCO2) was injected into core saturated with CO2-saturated brine to investigate brine displacement by scCO2. After sub-experiment S, unsaturated brine without any dissolved CO2 was flushed through the core to dissolve any trapped scCO2. X-ray fast scans were taken to monitor if all trapped scCO2 was removed, and to ensure the core was reset to fully saturated by unaturated brine. To investigate the coupling of brine displacement by scCO2 and the dissolution of the invading scCO2 into brine, sub-experiment series US (“US” for unsaturated) was performed by injecting scCO2 into the core filled with unsaturated brine. In both the sub-experiments S and US, scCO2 was injected at flow rate equaling 0.01 ml/min, and the corresponding capillary number (Ca) was at the order of 10^-9. Before any fluid flow experiment was conducted, a high-resolution base scan was acquired for core 01 and 02 at voxel size equaling 3.85 and 3.78 micron, respectively. For each of the four sub-experiments (S01, US01, S02, and US02), fast MCT scans were taken simultaneously to track the invasion pattern of scCO2. The resultant voxel size and acquisition time for core 01 (i.e. S01 and US01) equals 15.98 micron and approximately 30 mins, respectively. For core 02, the voxel size was reduced to 13.72 micron by moving the HTHP cell slightly closer to the X-ray source and increasing the voltage for the source. The acquisition time for each fast scans of core 02 (i.e. S02 and US02) were thereby reduced to approximately 16.5 mins. Subsequent image segmentation of the high-resolution dry scan was accomplished via a “Converging Active Contours” (CAC) routine, where the two physical phases, i.e. the air and the grain phase was identified by CAC based on chosen intensity thresholds. For the segmentation of the fast scans acquired during the drainage experiments, each scan was firstly partially segmented as the scCO2 phase and the combined brine and grain phase. The partially segmented fast scans were then overlaid with the segmented high-resolution dry scan for the identification of the brine and the solid phase. Subsequent noise removal of the segmented fast scans including removing scCO2 clusters that were smaller than sphere with radius euqaling 15 micron. In this dataset, data are in .nc format and can be read in ImageJ software via NetCDF plugins (http://www.unidata.ucar.edu/software/netcdf/). Datasets labelled as S0X and US0X were drainage experiments conducted using the same core under immiscible and partially miscible conditions, respectively, with X=1 or 2 labelling experiments conducted with core 01 or 02. Here, the numerals label datasets for each sub-experiments until the breakthrough of scCO2, with datasets in which scCO2 was firstly oberved labelled as 1, e.g. S01_1; "endpoint" labels datasets acquired at the end of each sub-experiment. This dataset contains data acquired until the breakthrough of scCO2 and at the end of each sub-experiment. The remaining datasets are available on request.
Contact Email
u5942786@anu.edu.au
Contact Address
Department of Materials Physics, Research School of Physics, The Australian National University, Canberra, 2601, ACT, Australia
Principal Investigator
Ruotong Huang
Supervisors
Anna Herring; Adrian Sheppard
Collaborators
Mohammad Saadatfar
Fields of Research
401199 - Environmental engineering not elsewhere classified; 410101 - Carbon sequestration science
Socio-Economic Objective
190301 - Climate change mitigation strategies
Keywords
Drainage; Capillary trapping; X-ray micro-computed tomography; Multiphase flow; Porous media
Type of Research Activity
Applied Research
Date of data creation
2023
Year of data publication
2025
Creator(s) for Citation
Huang
Ruotong
Herring
Anna
Saadatfar
Mohammad
Sheppard
Adrian
Publisher for Citation
The Australian National University Data Commons
Access Rights Type
Open
Licence Type
CC-BY - Attribution
Retention Period
Indefinitely
Data Size
40.5 GB
Data Management Plan
No

Download data files

Number of files: 22

Size: 40.5 GB

Identifier: anudc:6382

Status: Published
Published to:
  • Australian National University
  • Australian National Data Service
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