Abstract
AbstractTo better understand the stratigraphic development of sedimentary systems, it is necessary to link the controls on sedimentary processes to the resulting deposits, which in turn allows predictions of stratigraphic architectures at a range of scales. We use a stratigraphic forward model to link the governing parameters to the distribution of deposits within a distributive fluvial system (DFS). The numerical model has been validated against outcrop observations to establish how the depositional processes needed to form the specific sedimentary system have been reproduced. We chose the previously studied Oligocene to Miocene Huesca DFS in northern Spain to investigate and calibrate the model. Additionally, downstream profiles from modern DFS in northern India, and hydrological measurements from the High Island Creek, Minnesota, USA, were used as input parameters for the model in addition to the outcrop data from the Huesca DFS. The resulting model adequately reproduced the real‐world system. Once validated, the analysis of the modelled DFS led to key findings, which expand our understanding of DFS stratigraphic architecture. Reservoir characteristics in radial DFS are dependent on the angle away from the meridian (straight line from the source through the apex to the distal zone of the DFS). The greater the angle is, the coarser the average grain size in the proximal zone is but the finer the average grain size in the medial and distal zones. Lateral variability of net to gross, sandbody thickness and number, and amalgamation ratio is greatest at the transition between the proximal and medial zone and is still significant in the distal part of the DFS. Stratigraphic forward modelling enhanced our understanding of DFS, which leads to reducing risk associated with exploration, production and storage of fluids in subsurface DFS.
Highlights
To better understand the stratigraphic evolution of fluvial sedimentary systems, their controlling parameters need to be linked to their deposits
We show that this forward loop can be closed by using stratigraphic forward modelling through the following steps: Find a suitable distributive fluvial system (DFS) in outcrop to model, find modern systems for the governing parameters that cannot be derived from outcrop, build a stratigraphic forward model based on these measurable input parameters, use an iterative modelling workflow to adapt model input parameters not based on measurements until the modelled output closely aligns to the observed sedimentological parameters of the DFS in outcrop and use the resulting stratigraphic forward model of the DFS to improve our understanding of this sedimentary system
We used the hydrodynamic stratigraphic forward modelling software Sedsim to reproduce the main characteristics of a DFS as constrained by outcrop measurements from the Huesca system
Summary
To better understand the stratigraphic evolution of fluvial sedimentary systems, their controlling parameters need to be linked to their deposits. Hydrodynamic stratigraphic forward models (SFM) require no prior knowledge of the depositional geometry such as channel planform, as physical formulas for fluid flow and sediment erosion, transport, and deposition compute the distribution of sediments over natural temporal and spatial scales. This echoes Best and Fielding (2019) who said that the step in describing fluvial systems is to link processes to deposits and stratigraphy. They proposed the use of facies models which should be based on physical process distinctions to achieve this step. The numerical or facies models will lead the way to a predictive model of sediment body architecture, which is crucial for derisking subsurface exploitation and storage of fluids (e.g., hydrocarbons, ground water, geothermal energy, hydrogen and carbon dioxide) in these sedimentary systems
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