BRUCE D. TRUDGILL
RESEARCH
1. Salt tectonics
A. The Paradox Basin in SE Utah
The Paradox Basin is an asymmetric foreland basin, developed along the southwestern flank of the Uncompahgre uplift in southeast Utah and southwest Colorado, USA. This large basin (265km by 190km) developed during the Middle Pennsylvanian-Permian Ancestral Rocky Mountain orogenic event. Salt structures in the northern Paradox Basin form a variety of structural styles ranging from deeply buried salt pillows to complexly faulted diapirs and salt walls exposed at the surface. Complex intra-formational unconformities and rapid lateral stratigraphic facies variations indicate that salt structures were active over at least 75 Ma.
Analysis of field exposures, sub-surface well and 2D seismic data across the northern part of the basin reveals a complex relationship between crustal shortening, loading, creation of accommodation space, differential sedimentation and salt movement. Salt flow through time across the northern part of the basin reflects the varying basin geometry and its response to sediment depositional systems. From the early stages of salt movement in the Upper Pennsylvanian, through passive growth of a series of large (up to 4 km high) salt walls, the dynamics of salt movement were a strong control on both structural development and stratigraphic facies architecture.
(Abstract from Trudgill, B.D., Banbury, N., and Underhill, J.R., 2004, Salt Evolution as a Control on Structural and Stratigraphic Systems: Northern Paradox Foreland Basin, SE Utah, USA, in GCSSEPM 24th Annual Research Conference)
Outstanding exposures in the Paradox Basin, SE Utah
Structures in the northern Paradox Basin (after Doelling, 2002)
Salt controlled stratigraphy on the banks of the Colorado River near Moab, Utah
Exposures along the flank of the Onion creek salt diapir in the Paradox Basin
Satellite view of the Colorado Plateau and eastern Basin and Range
Bathymetry of the Gulf of Mexico (image courtesy of Shell) showing the complex geometry of the Sigsbee salt nappe
Salt systems of the northern Gulf of Mexico (after Diegel et al., 1995)
Sample seismic profile showing salt geometry (black) and dasted horizons in the West Delta/South Pass area
Three-dimensional depth models of salt systems in the West Delta/South Pass area, offshore Louisiana, Gulf of Mexico: (A) Map view of the simplified 3-D model. Present day salt is shown in pink, salt welds in red, counter-regional “fault welds” in green, and two large roller faults from an adjacent roho system in blue. (B) Perspective view of the simplified 3-D model viewed from the north; (C) View towards the southwest with faults and fault welds removed to highlight the multi-layered and linked geometry of the salt systems. The depth model was constructed using Midland Valley’s 3Dmove software. Tick marks on frame edges in (a) and (b) are spaced every 10 km, but the scale in each frame varies because of the perspective view.
3D Movie of the West Delta/South Pass salt systems
Animation of the simplified 3-D depth model of the WDSP salt system constructed using Midland Valley’s 3Dmove. Present day salt is shown in pink, salt welds in red, and counter-regional “fault welds” in green.
Animation of the 2-D restoration of a cross section across the Dome A system (line orientation shown in Fig. 8), constructed using 2DMove and the methodology of Rowan (1993). Salt is in black, and pairs of dots indicate salt welds. See also Fig. 10 and text for detailed discussion.
Animation of 3-D restorations for the WDSP study area constructed using
3DMove from 9.10 Ma to the present day. Views are from the northeast.
Volumes of salt at each stage are shown in bright pink. Welds that develop
during evolution of the salt system are shown in red and late stage
counter-regional “fault welds” in green.
Salt structures revealed by seismic reflection data from offshore Brazil
Anticlines pierced by salt diapirs in the Zagros foldbelt, Iran
Detailed satellite image of a salt glacier flowing from a salt diapir in Iran
In southern Iran, the collision between the Asian landmass and the Arabian platform has folded rocks and pushed up the rugged Zagros Mountains. In places, underlying deposits of salt have ascended in fluid-like plumes. Some of these plumes have pushed through the rock above, like toothpaste from a tube, and they are now visible as darkish irregular patches. This image shows a few of over 200 similar features—called diapirs, or salt plugs—that are scattered about this part of the Zagros Mountains.
Gravity has caused the salt to flow like glaciers into adjacent valleys. The resulting tongue-shaped bodies are more than 5 kilometers long, with repeating bow-shaped ridges separated by crevasse-like gullies and with steep sides and fronts. The darker tones are due to clays brought up with the salt, as well as the probable accumulation of airborne dust. This ASTER perspective view was created by draping a band 3-2-1 (RGB) image over an ASTER-derived Digital Elevation Model (2x vertical exaggeration), and was acquired on August 10, 2001.
Image courtesy NASA/GSFC/MITI/ERSDAC/JAROS, and U.S./Japan
2. Growth of normal fault systems
A. The Canyonlands Grabens of SE Utah: A natural laboratory for
examining fault growth
The Canyonlands Grabens in southeast Utah form an active extensional fault array covering 200 km2 southeast of the Colorado River in Canyonlands National Park. The fault array formed as a result of gravity gliding above a thick layer of salt. Growth of this fault array within the last 0.5 my (possibly last 0.1 my) has produced a spectacular array of linked normal fault geometries. A wide variety of relay ramp structures are developed in regions of fault overlap, and their evolution can be clearly defined in the field.
The rapid growth of the fault array resulted in major changes in the stream drainages across the area through processes of stream capture and diversion. During growth of the fault array, relay ramps between overlapping fault segments form topographic lows along the graben margins. These commonly act as access points for captured streams to enter a graben system. As fault segments continue to propagate laterally, linkage leads to breaching of the relay ramp structures. This causes changes in the course and gradients of the streams, often shifting the locus of alluvial sediment deposition away from grabens that were previously infilling. This complex evolution of drainage networks in a growing fault array may provide a valuable analogue to the early structural and stratigraphic development of larger continental rifts systems.
Current research is now focused on obtaining rates of fault growth from an integrated analysis of drainage evolution with dating techniques and GPS measurements. This will ultimately lead to constraints on the evolution of the fault array through time and help enhance our understanding of fault growth processes.
The geometry of the fault array at depth is less well constrained in the field. However, the presence of a salt detachment level 500m below the land surface means that models of graben formation and vertical fault propagation can also be tested in this unique natural laboratory. By happy coincidence the Canyonlands Grabens lie within one of the most spectacular National Parks in the United States, and are reasonably accessible to geologists keen to examine these features for themselves.
Detailed map of the Canyonlands Grabens fault array illustrating the present day
geometry of the fault array (red), current stream drainages (blue), and
interpreted paleo-drainage patterns prior to graben development (dashed black
lines)
DEM
of the Canyonlands Grabens fault array A
view across the growing fault array in the Canyonlands Grabens, SE Utah
Oblique, low altitude aerial photographs of the southeast margin of the
Canyonlands Grabens fault array A)
USGS aerial photograph of the region around Cow Canyon. Shifting Wash, a major
tributary to Butler Wash traverses the eastern side of the image from south to
north. (B) Interpretation of fault geometries, modern streams and paleo-drainages
(dashed lines) across the Cow Canyon area. Prior to the development of the fault
array, stream drainages ran southeast to northwest across the area. Numbered
paleo-drainages illustrate the interpreted history of channel switching of
Shifting Wash.
Large
scale grabens in the Afar area of the East African rift system
3.
Evolution of Mountain Belts
Utah/Wyoming thrust belt
Cordillera mountain ranges of Colombia The
western French Alps, my PhD field area
Central Nepal Himalaya,
Everest right of centre
4.
Structural controls on depositional facies architecture
A structurally controlled
alluvial fan in the Taklimakan Desert, China
Rock outcrops are the foundation upon which the
geological sciences are built, and the source of much of our knowledge of
sedimentary and structural geology that together yields the architecture of
hydrocarbon reservoirs. This is underscored in deep marine environments, where
modern sedimentary processes and responses to structural movement cannot be
readily observed. The research proposed combines traditional field observation
with state-of-the-art 3D modeling technology to effectively use outcrop models
to improve reservoir prediction and simulation through investigation and
verification of geologic controls on reservoir architecture and interrogation of
how we manage this information in reservoir modeling. This will be achieved
through the construction, analysis and experimentation of 3D geologic,
petrophysical and geophysical models, initially in Project I, building on
existing models from Permian deep-water strata of the Brushy Canyon Formation.
The Brushy dataset permits us to refine the outcrop to subsurface data
conversion workflow for experimentation of fine-scale and high-resolution
outcrop models, create an integrated CVX-CSM modeling team and define the
modeling experiment workflow, and conduct numerous experiments on an existing
model where we can efficiently test geologic rules and subsurface data analysis
methods that will guide selection of the outcrop(s) to be studied in Project II.
Project II integrates structural methods to investigate the affect of structural
movements on deep-water sedimentary patterns. Criteria for demonstrating a
structural-sedimentary linkage, methods required to document these effects,
screening of candidate outcrops, and review of the literature will guide
selection of one or more outcrops for Project II study, where the role of
synsedimentary structural development on deep-water sedimentation patterns will
be investigated.
We propose two
concurrently running projects in the first two years of this research program,
with the expectation that methods and learning will be fully integrated in year
three as the program moves forward with study of new outcrop(s) that focus on
the role of synsedimentary structural development on deep-water sedimentation
patterns.
Project I: Testing and Developing Rules for Reservoir Prediction
Leveraging off the Slope &
Basin Consortium the project will refine an existing deterministic The primary
objective of the proposed research is to develop “Rules” that can be used to
predict reservoir properties (stratigraphy, geometry, facies, petrophysics) in
sparse well settings. These “Rules” will be generated through observation,
parameter correlation and verification using a family of deterministic outcrop
models. This includes the flow response to varying reservoir architectures for
better reservoir performance prediction. Flow relevance will be interrogated and
assessed through iterative streamline analysis and flow simulation of full field
and sector models. Project II will investigate how these stratigraphic rules
change as a function of structural setting.
Project II: Structural-Stratigraphic Linkage in Deep-Water Sedimentation The
main aim of this new project is to assess the influence of structural processes
on the stratigraphic architecture of deepwater reservoirs. We propose to begin
the screening and selection of syn-sedimentary structures in outcrop where we
can expand the reservoir modeling tools that incorporate detailed outcrop data,
as outlined in Project I. The initial goals of this project are to develop
screening criteria and efficient methodologies to select the outcrops that will
provide data for a new phase of study that will build on the predictive modeling
tools developed from the Brushy Canyon data. An additional goal will be to
define a workflow for the evaluation of outcrop sites and data sets.
Growth folds in the
Laingsburg basin in South Africa
Growth folds in the Jaca
Basin, southern Pyrenees World
topograghy and bathymetry The
Basin and Range province in the western USA
Composite satellite image of the British Isles West
Wales around the Dyfi and Mawddach estuaries and the Cadair Idris and Pumlumon
mountain ranges
Evolutionary
model for part of the Canyonlands Grabens system (area covers Cow, Cleft and
Bobby Joe Canyons), based on aerial photograph and field interpretations. (A)
Initial SE to NW stream drainages are unaffected by small, unlinked fault
segments. (B) Extension becomes localized on a number of evenly spaced,
overlapping fault segments. With the formation of shallow grabens, some streams
are redirected, and locally thick alluvial sediments accumulate within some of
the grabens (e.g., Cow Canyon). (C) Hard linkage of the fault segments further
modifies the stream drainages. Many grabens now have only localized drainage
systems. The main stream drainage bypasses most of the area to the northeast.
Reducing
Uncertainty in Interpretation of Subsurface Geology Through Application of 3D
Outcrop Models
Colorado
School of Mines –
Chevron
Texaco
Center of Excellence
Cape fold Belt and Karoo +
Laingsburg basins in South Africa
5.
Tectonic geomorphology
