Finite Strain with large rotations: A new hybrid numerical/experimental approach. Deformation up to large strains and rotations is important in rocks, metals, polymers, and biomaterials. Computational mechanics is a standard tool for modelling such deformations. However, in earth sciences, mechanical theories use small-strain formulations or large-strain approaches with classical stress rates. Classical stress rates can lead to incorrect stored energies. This project proposes to test a new large ....Finite Strain with large rotations: A new hybrid numerical/experimental approach. Deformation up to large strains and rotations is important in rocks, metals, polymers, and biomaterials. Computational mechanics is a standard tool for modelling such deformations. However, in earth sciences, mechanical theories use small-strain formulations or large-strain approaches with classical stress rates. Classical stress rates can lead to incorrect stored energies. This project proposes to test a new large-strain theory tailored to rocks experimentally, and to apply it to a pivotal geological problem: shear zone formation. The project will advance our fundamental understanding of the mechanics and energetics of rock deformation and provide a novel tool for the modelling of large deformations.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100050
Funder
Australian Research Council
Funding Amount
$970,000.00
Summary
A new national electron microprobe facility. A new national electron microprobe facility: Precise chemical microanalysis underpins research on Earth materials. The Electron Microprobe (EMP) is the main instrument to achieve this. It performs rapid quantitative analysis and element mapping on solid materials at micron resolution. This facility will support an impressive variety of research including experimental, igneous and metamorphic petrology and geochronology. It will foster increased collab ....A new national electron microprobe facility. A new national electron microprobe facility: Precise chemical microanalysis underpins research on Earth materials. The Electron Microprobe (EMP) is the main instrument to achieve this. It performs rapid quantitative analysis and element mapping on solid materials at micron resolution. This facility will support an impressive variety of research including experimental, igneous and metamorphic petrology and geochronology. It will foster increased collaboration between partner organisations including universities and major geoscience institutes.Read moreRead less
Pressure waves on the mechanics of earthquakes and faulting. This project aims to decipher the physics of faulting and earthquakes from damage zones around seismogenic faults. It will examine a mechanism for instability in solids: volumetric collapse due to a dissipative pressure wave. This pressure wave may control damage-zone geometry and relate to earthquake stress and rock material properties. The project will research the instability through theoretical, laboratory and field studies. Antici ....Pressure waves on the mechanics of earthquakes and faulting. This project aims to decipher the physics of faulting and earthquakes from damage zones around seismogenic faults. It will examine a mechanism for instability in solids: volumetric collapse due to a dissipative pressure wave. This pressure wave may control damage-zone geometry and relate to earthquake stress and rock material properties. The project will research the instability through theoretical, laboratory and field studies. Anticipated outcomes include advances in earthquake and fault prediction, tools to determine the stress state and material properties of Earth’s crust, and knowledge of a class of solid instabilities.Read moreRead less