Upscaling laws for hydraulic fracturing of tight formations using reproducible true tri-axial laboratory testing. Upscaling models for designing hydraulic fracture stimulation of gas reservoirs will be developed. Innovative laboratory methods of reproducing the field stress conditions and rock structure will be used. The results will advance the mechanics of hydraulic fracturing and increase efficiency of reservoir stimulation, especially in tight formations.
Quantification of Multiphysics phenomena of Gas flow in organic rich shales. We address the scientific question of the nature of gas extraction from nominally impermeable rocks such as shales. Our main aim is to develop a fully coupled microstructurally enriched thermodynamic continuum model to predict the Multiphysics behaviour of shale reservoirs during gas production and verify the model with representative experiments conducted on formations from three Australian Basins including Cooper, Per ....Quantification of Multiphysics phenomena of Gas flow in organic rich shales. We address the scientific question of the nature of gas extraction from nominally impermeable rocks such as shales. Our main aim is to develop a fully coupled microstructurally enriched thermodynamic continuum model to predict the Multiphysics behaviour of shale reservoirs during gas production and verify the model with representative experiments conducted on formations from three Australian Basins including Cooper, Perth and Beetaloo, where the samples are available to the investigators. We approach this problem in a hybrid theoretical-numerical-experimental study. This is the first international attempt to develop such experimentally verified thermodynamic based model, particularly for Australian shales.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100209
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
A 4-D X-Ray Microscopy Laboratory. We propose a multiscale X-Ray Microscopy (XRM) laboratory for time-lapse imaging. High flux X-Ray Microscopy (XRM) with resolutions from cm- down to Angstrom-scale is proposed by bringing Synchrotron technology to the laboratory. The laboratory aims at revolutionising imaging capability of evolving structures and physical properties in inorganic and organic materials used in mineral, energy, manufacturing, bioengineering, aerospace, automotive and a range of ot ....A 4-D X-Ray Microscopy Laboratory. We propose a multiscale X-Ray Microscopy (XRM) laboratory for time-lapse imaging. High flux X-Ray Microscopy (XRM) with resolutions from cm- down to Angstrom-scale is proposed by bringing Synchrotron technology to the laboratory. The laboratory aims at revolutionising imaging capability of evolving structures and physical properties in inorganic and organic materials used in mineral, energy, manufacturing, bioengineering, aerospace, automotive and a range of other industries. The expected outcome is an integration of XRM between USyd, UNSW, UQ, QUT and ANSTO. The added benefit is to perform long time scale XRM experiments with collaborations in the material- manufacturing, geo- and biomedical sciences and many engineering disciplines.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100095
Funder
Australian Research Council
Funding Amount
$620,000.00
Summary
High-resolution X-ray micro computed tomography supporting West Australian geo-, physical and biological science. An X-ray micro computed tomography facility will provide West Australian researchers with much needed access to cutting-edge instrumentation for high-resolution three-dimensional imaging. This facility will support major research programs in key disciplines, including minerals and mining, energy, medical and biological sciences.