2 research outputs found
4-dimensional study of dissolution precipitation creep in oedometric compaction experiments of NaCl-biotite aggregates
Understanding the dynamic evolution of hydraulic rock properties and the
associated deformation mechanisms is a crucial factor in establishing the potential
of groundwater resources, geological repositories as well as fossil fuel reservoirs.
Chemical compaction by dissolution precipitation creep (DPC) is a major ductile
deformation mechanism in the Earth’s upper crust that affects the porosity and
permeability of its host rock and therefore influences transport properties and fluid
flow herein. However, investigations of the process were in the past limited to
observations on natural samples, laboratory experiments and numerical modelling,
either lacking a temporal or spatial component or the validation of the model by
direct observations. The link between space and time only became possible recently
with the implementation of X-ray computed microtomography (microCT) in the
earth sciences. By means of microCT imaging time-resolved, three-dimensional data
(4D datasets) can be used to investigate the dynamic spatio-temporal evolution of
hydraulic properties and the effect of mechanical-chemical feedback mechanisms.
This thesis investigates slow chemical compaction mechanisms and their
influence on porosity in NaCl-biotite rock-analogues. Oedometric compaction
experiments on samples of different compositions and structures (layered vs.
homogeneous) were conducted and time-resolved (4D) microtomographic data used
to capture the dynamic evolution of the transport properties with progressing
compaction. Furthermore, emphasis was placed on the effect of phyllosilicates
upon deformation by dissolution precipitation creep, which is generally regarded to
reinforce the process.
Percolation analysis in combination with advanced digital volume correlation
techniques showed that the presence of phyllosilicates influences the dynamic
evolution of the porosity in the samples by promoting a reduction of porosity in
their vicinity to the point of disconnecting the pore volume. However, the absence
of strain localisation around those phyllosilicates and a homogeneous distribution
of axial shortening across the samples invites a renewed discussion of the effect of
phyllosilicates on dissolution precipitation creep, with a particular emphasis on the
length scales of the processes involved.
The results presented in this thesis, are among the first spatial-temporal data
sets resolved on the microscale that demonstrate the crucial role of dissolution
precipitation creep for the dynamic evolution of fluid transport properties. In addition
to that, they encourage discussing classical theoretical models of diffusive transport
and give an insight into the remaining challenges of experimental dissolution
precipitation creep, especially concerning the nucleation and growth of stylolites