Abstract
Salt diapirs can be asymmetric both internally and externally reflecting
their evolution history. As such, this asymmetry bear a significant
amount of information about the differential loading (± lateral
forces) and in turn the salt supply that have shaped the diapir. In two
dimensions, In this study we compare results of analogue and numerical
models of diapirs with two natural salt diapris (Klodawa and Gorleben
diapirs) to explain their salt supply and asymmetric evolution. In a
NW-SE section, the Gorleben salt diapir possesses an asymmetric external
geometry represented by a large southeastern overhang due to salt
extrusion during Middle Cretaceous followed by its burial in Tertiary.
This external asymmetry is also reflected in the internal configuration
of the diapir which shows different rates of salt flow on the two halves
of the structure. The asymmetric external and internal geometry of the
Gorleben diapir reflect an asymmetric salt supply driven by an
asymmetric differential loading. The Klodawa Salt Structure of
Poland is also an asymmetric salt structure driven by asymmetric
differential loading from the overlying sediments. The KSS is a salt
ridge built of Zechstein evaporite series located in the axial part of
the former Mid-Polish Trough. This extensional basin was filled with
Zechstein to Cretaceous sediments and was inverted in the Late
Cretaceous to Paleogene time. The diapir was triggered in Triassic above
a basement fault. In late Triassic, after intruding cover sediments, the
diapir extruded an overhang. Using the asymmetric Klodawa Salt
Structure (KSS) in central Poland as a prototype, a series of analogue
models were carried out to investigate the evolution history and salt
supply driven by asymmetric differential loading. During extension of
the model, a daipir was upbuilt by the sand cover above the basement
fault. The ductile layer was allowed to extrude a wide overhang at the
model "late Triassic" time. The diapir was later downbuilt with
progressive extension. At the end of the extension, a part of the model
was sectioned for photographing, whereas the remaining part was inverted
resulting in uplift of the hanging wall portion of the model. The model
was eventually buried and sectioned for photographing. The experiments
showed that at an early extensional stage, the diapir was primarily fed
from the footwall side. Footwall material constitutes the uppermost
portion of the structure and the dominant component of the overhang.
Taking the top of the prekinematic layer as a reference line, footwall
material made up between >90% at the initial stage of the diapir to
about 75% in the mature diapir (Fig. 1a). Reverse movement on the
basement fault resulted in an increase in the diapir height, overall
thinning of its stem and larger supply of the ductile layer from the
hanging-wall side into the diapir. After the inversion, the hanging-wall
material constituted 35-45% of the structure and it was dominantly
located in the diapir stem. Model results show that asymmetric diapir
reflect a differential salt supply which is driven by an asymmetric
sedimentation and hence differential loading on either side of a salt
diapir.
| Original language | English |
|---|---|
| Journal | Geophysical Research Abstracts |
| Volume | 14 |
| Pages (from-to) | 10365 |
| Number of pages | 1 |
| ISSN | 1607-7962 |
| Publication status | Published - 2012 |
| Event | EGU General Assembly 2012 - Vienna, Austria Duration: 22 Apr 2012 → 27 Apr 2012 |
Conference
| Conference | EGU General Assembly 2012 |
|---|---|
| Country/Territory | Austria |
| City | Vienna |
| Period | 22/04/2012 → 27/04/2012 |