Landscape evolution of the Umbum Creek Catchment, Western Lake Eyre, Central Australia.

Waclawik, Victor G.

January 2006

Landscape evolution is important for mineral and petroleum exploration concepts, especially in dryland continental settings. This study seeks to understand the main issues and controls on landscape evolution that have produced the regolith and young sediments around the western side of Lake Eye, in the arid heart of Australia. Several methods were employed including satellite image analysis, geomorphometry, geological mapping, regolith mapping and surveying. Outcomes indicate that the underlying structural fabric of the basement has controlled the development of the surface morphology of the Umbum Creek Catchment. The arrangement of basement faults is reflected in the distribution of surface landforms and in the topography of the land surface. Significant deformation of the Etadunna and Eyre formations indicate tectonic activity occurred at the end of the Miocene and was probably related to movement in the Lake Eyre Fault Zone. Pleistocene faulting is expressed as minor blind faulting associated with pre - existing basement faults. These faults remain active and current seismic activity is driven by changes in hydrostatic pressure (hydroseismicity). The scale of Pleistocene faulting and modern seismic activity demonstrates that since the Pliocene tectonic activity has been subdued. Climate change caused landforms developed under wet conditions during the Palaeogene and Neogene to be preserved by the development of aridity in the Pleistocene. High erosion rates associated with tectonism and the onset of aridity in the Pleistocene led to topographic inversion of many features. Palaeo-Proterozoic inliers formed inselbergs, silcrete outcrops formed capstones, gypsum hardpans protected underlying sediment from erosion creating plateaux of gypsum patterned ground and palaeo-channels on the Neales Fan were eroded to make heavily armoured mounds and associated sand dunes and sand sheets. The dominant factor influencing the evolution of the landscape in the Umbum Creek Catchment was the deposition of sedimentary sulphides within the Bulldog Shale. The excess sulphur that this sediment supplied to the landscape over time created the necessary conditions for the formation of a range of landscape features that would not otherwise exist. Weathering, oxidation and leaching of the sedimentary sulphides led to the development of silcrete. Subsequent weathering and tectonic activity led to the breakdown of the silcrete and the distribution of silcrete pebbles widely across the landscape forming gibber plains. Sulphur from the Bulldog Shale continued to contribute to the landscape forming intra-formational gypsum and precipitating as gypsum hardpans. This study has implications for petroleum exploration in dryland continental settings as potential reservoirs may be affected by secondary diagenetic processes, such as the formation of gypsum or silcretes, that could act as baffles or result in reduced porosity within the reservoir. The broad-scale architecture of fluvial systems, like the Neales Fan, may not conform to traditional fan-shaped models being, instead, comprised of structurally rearranged channels. In terms of earthquake risk assessment, the identification of hydroseismicity active within the Lake Eye Basin allows for a new level of predictability of earthquake behaviour within Central Australia. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1260856 / Thesis (Ph.D.) -- School of Earth and Environmental Sciences, 2006

Landforms Australia Eyre, Lake, Basin.

The Origin and Evolution of Active Spreading Segments in the Northern Lau Basin

Ryan, Michael

23 January 2024

Extension at oceanic spreading centers ranges from ultra-slow (dominantly tectonic) to ultra-fast spreading (dominantly magmatic). This variation is reflected in the morphology of the spreading ridge segments and the magmatic productivity observed on the seafloor. These relationships are well understood at Mid-Ocean Ridges (MOR), but less is known about spreading centers above subduction zones. This study is part of a larger initiative to create the first 1:1,000,000 scale geological maps of different subduction zones at the Indo-Australian margin. This is a region of some of the fastest-growing crust on Earth and exhibits prolific magmatic-hydrothermal activity in back-arc basins. Previous work has shown that crustal growth associated with westward subduction of the Pacific Plate is characterized by highly distributed extension in back-arc basins, with numerous and simultaneously active spreading centers. In the NW Lau Basin, two of the spreading centers are punctuated by large-scale magmatic centers that coincide with anomalous mantle input (as documented by large-scale mantle helium anomalies) − features that are not well known in other basins. Detailed mapping at 1:200,000 scale shows that these spreading centers are related to near-field transcurrent faulting that developed in the early stages of the Lau back-arc basin. Translation across two oppositely moving fault zones induced rotation of the intervening crust and two anomalous spreading centers (Rochambeau Rifts and the Northwest Lau Spreading Center) opened obliquely to these structures. Both show inflated axial volcanic ridges that may be a product of an anomalous melt supply relative to the spreading rate. The marked variation in the morphology and magmatic output are thought to be controlled by input of melt from adjacent sources (Samoan plume) or the channeling of melt into a zone of thicker pre-existing crust, or both. These findings have important implications for understanding the origins of large-scale magmatic input in back-arc basins, where many fossil ore deposits have formed, thus providing important guides for resource exploration in ancient volcanic terranes on land.

Back-arc Basin Volcanism

Lau Basin

Back-arc Basin Magmatism

Remote predictive mapping

Crop production, soil erosion, and the environment in the Maumee River Basin : a modelling approach /

Abraham, Girmai,

January 1981

No description available.

Economics

Crops and soils--Maumee River Basin

Soil erosion--Maumee River Basin

Environmental policy--Maumee River Basin

LATE PLEISTOCENE AND HOLOCENE ENVIRONMENTS IN THE GREAT BASIN.

THOMPSON, ROBERT STEPHEN.

January 1984

Pollen and packrat midden data from the Great Basin indicate that the Pleistocene vegetation of the region was a combination of subalpine conifers on coarse substrates and steppe plants on finer valley bottom soils. While some of the modern dominants of the woodland zone were apparently absent from this region, other woodland and montane plants apparently persisted through the late Pleistocene. Some features of the Pleistocene environment, such as the large pluvial lakes, apparently disappeared by 12,000 yr B.P., while subalpine plants remained well below their modern elevational limits after 11,000 yr B.P. Limber pine and Rocky Mountain juniper apparently did not retreat from the lower mountain slopes until after 6500 yr B.P. Montane and woodland conifers, rare or absent in the region during the Wisconsin, dispersed across the region in the Middle Holocene. Other plants apparently did not reach their modern geographic limits until after 3000 yr B.P. The low elevational occurrences of subalpine species suggest that the late Pleistocene climate of the Great Basin was characterized by summer temperatures that were as much as 10°C cooler than those of today, and that there was some augmentation in the level of mean annual precipitation. The vegetational records provide no evidence of greater than modern levels of summer precipitation. While the persistence of montane plants at relatively low elevations implies cool or moist conditions through the Early Holocene, evidence from lacustrine systems suggests that there was a trend toward increasingly dry conditions during this period. The main period of migrations of woodland plants seems to slightly postdate the warmest and/or driest part of the Holocene, and these migrations may have been related to relatively high levels in summer temperatures, summer precipitation, and/or winter temperatures. Pollen data from a high elevation site, in conjunction with changes in water level in lower elevational lakes, suggest a return to cooler and/or moister conditions after 4000 yr B.P.

Geology, Stratigraphic -- Pleistocene.

Geology, Stratigraphic -- Holocene.

Paleobotany -- Great Basin -- Holocene.

Great Basin.

The phanerozoic basin-fill history of the Roebuck Basin

Smith, Stuart A. (Stuart Andrew)

January 1999

Bibliography: p.149-158. Aims to provide a structural and stratigraphic framework for the evolution of the Roebuck Basin, and to evaluate its future petroleum potential.

Roebuck Basin (W.A.)

Numu views of Numu cultures and history : cultural stewardship issues and a Punown view of Gosiute and Shoshone archaeology in the northeast Great Basin

Brewster, Melvin G., 1960-

12 1900

xvi, 187 p. : ill., maps. A print copy of this title is available through the UO Libraries under the call number: KNIGHT E99.N97 B74 2003 / The culture history of the northeastern Great Basin, as currently written by the archaeological profession, is silent as to the view of Gosiute and Shoshone natives about their own ancestors. The goal of this dissertation is the infusion of Punown (interrelated Numic speaking peoples) epistemology into mainstream anthropological interpretation, as provided through North American Desert West prehistory. The hypothesized Numic expansion into the Northeast Great Basin, according to which the Punown natives now resident throughout the region are very recent immigrants, is problematic on several grounds. In the dissertation I show that late population movement into this region by Numic ancestors has not been demonstrated. After a hundred years of research no consensus yet exists as to the origins of the Northern Uto-Aztecan speaking Numic peoples (Punown). In spite of that, and in spite of the fact that it takes no account of the natives' own view of their origins, the Numic Expansion Hypothesis is being used in a way by some archaeologists and cultural resource managers that denies to the Punown their cultural heritage. The archaeological record of the region, extending back into deep time, is rich in the similarities it shows with the native Punown cultures of the contact-historic period. The epistemology and spiritual beliefs of the Punown also assert their cultural continuity with the ancient traditions documented in that archaeological recoret;It is not acceptable that a scientific hypothesis impedes native people's role in the care and stewardship of sites and places throughout the region that their own spiritual traditions tell them they are responsible for. The mainstream anthropological concept of science and the epistemology of the Punown are opposed diametrically. Punown view the world and its people as interconnected through the Sacred Earth Matrix, while anthropologists see the human world as bifurcated from nature. Punown understand archaeology and relatedness spiritually, while archaeologists see dead objects in an "objectified" way. Conformity to the existing paradigm, with its persistent building and rebuilding of earlier untenable Euroamerican views of Numic origins, makes the Punown outsiders to the region in which they live. This goes on even though many scholars, reviewing the case for a Numic Expansion, find it seriously lacking. Infusion of Punown epistemology into current archaeological practice offers a basis for pooling Punown and mainstream anthropological approaches to the prehistory of the Desert West. A mutually enhancing research partnership based on beneficial objectives is advocated; this will go far to repair a strained relationship that now exists between Punown and archaeological researchers, and result in a fuller and richer history for all to contemplate. / Committee in Charge: Dr. C. Melvin Aikens, Chair; Dr. Jon Erlandson; Dr. Lawrence Sugiyama; Dr. Scott DeLancey

Uto-Aztecan Indians -- Historiography

Archaeology -- Great Basin

Anthropology, Prehistoric -- Great Basin

Great Basin -- Antiquities

Geochemical impact of super-critical C02 injection into the St. Peter Sandstone Formation within the Illinois Basin : implication for storage capability in a carbon dioxide sequestrian system

Thomas, Richard Michael

January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Deep injection of waste CO2 and fluids from regional energy plants into the St. Peter Formation of the Illinois Basin, could effectively provide long term deep geologic storage. This research aims to explore the viability of this proposed injection. There are some basic criteria that must be met to effectively store waste in a geologic reservoir. First, the reservoir must have sufficient porosity and permeability for both injectivity and for migration of the injected fluid through the reservoir. Second, the reservoir must be overlain by some form of impermeable seal or cap layer(s). Third, the reservoir should be sufficiently isolated from interaction with surface and near surface water. Finally, the formation must contain enough storage volume to handle significant amounts of injected material. Massive sandstone formations that host large saline aquifers have the potential to serve as high capacity storage sites. Much of the research targeting the potential suitability and storage capacity attributes of these formations has been promising, but reproducibility of the results has been less than ideal. Some of this variability has been attributed to petrological differences in the sandstone reservoirs that are not readily evident when studying the target formation over a geographically significant area. Based on the criteria, a promising candidate for injection and storage is the St. Peter Sandstone of the Illinois Basin. This study investigates the viability of liquefied CO2 storage within the St. Peter Sandstone on a micro scale. Initial porosity and permeability of the formation plug samples ranged from 16% to 19% and 26 to 981 millidarcies (mD), respectively. The wide difference in permeability is attributed to variations in strength of the cement, in this case quartz overgrowth in the sandstone. This preliminary evidence indicates that the storage capacity of the formation will remain constant or increase depending on injection location, suggesting that the St. Peter Formation will lend itself well to future storage.

Geologic Storage

Illinois Basin

Deep geologic disposal -- Illinois Basin

Energy industries -- Waste disposal

Sandstone -- Illinois Basin

Formations (Geology) -- Illinois Basin

Analysis of gravity data from the Picacho Basin, Pinal County, Arizona

Christie, Fritz Jay

January 1978

No description available.

Water table -- Arizona -- Picacho Basin.

maps

Facies variability in deep water channel-to-lobe transition zone : Jurassic Los Molles Formation, Neuquen Basin, Argentina

Tudor, Eugen Petrut

04 September 2014

This study focuses on the facies changes from the lower slope to toe-of-slope to basin floor over a 10 km outcrop belt, in down-dip and oblique-strike directions to the basin margin. The Jurassic Los Molles Formation in Neuquen Basin, Argentina represents the slope and basin floor of basin margin clinoforms, coeval with the shallow water and fluvial deposits named Las Lajas and Challaco formations respectively. The shallow and deep water deposits are diachronously linked in an Early-Mid Jurassic source-to-sink system developed in a back-arc basin during the incipient development of the Andes Mountains. Satellite images, high resolution panorama pictures and measured sections were used to correlate and interpret the spatial variability and overall geometry of the base of slope to basin floor units. The observations of this study refine the model for the channel-to-lobe transition zone with increase recognition and quantification of facies and architecture variability. The Los Molles basin margin was coarse grained and was ideal to observe changes in the geometry and depositional facies of channel-to-lobe deposits from updip to downdip continuous over an 8 km outcrop belt. The described channel-to-lobe transition zone clearly shows a downdip change in bed boundaries from dominantly erosive to non-erosional (bypass) to depositional and with a range of distinct facies changes. In the transition zone the sand to shale ratio is high (N:G: 65-70 %), with gutter casts and deep scours, with a high degree of amalgamation, gravel lags, mud rip-up clasts and laterally migrating beds. Within the same depositional unit (deep water lobe), at the base of the slope, the dominant sandstone beds change from amalgamated structureless and normal graded sandstone beds in the channelized lobe axis to parallel laminated and normally graded in the channelized lobe off-axis areas. Similar facies changes have been observed along proximal to distal direction. The lateral change of the dominant structures in the beds indicates changes in the flow regime and depositional style. / text

Slope to basin floor

Channel-to-lobe

Facies

Transition

Neuquen Basin

Deep water basin margin

Los Molles Formation

Jurassic

Argentina

Patterns of infull and basin-scale architecture : Tyee Forearc Basin, and observation from a segment of New Jersey passive margin

Santra, Manasij

10 October 2014

The well-known clinoformal geometry of a basin-fill, with an alluvial to shelf segment, deep-water slope segment, and a basin floor segment, arises from the development of a wedge-shaped body of sediment at the basin-margin that has been termed a basin-margin wedge or a shelf-slope sedimentary prism. The basin-margin wedge characteristically has atopset-foreset clinoformal geometry, with its topset dominated by alluvial, coastal and shelfal processes, while its foreset is dominated by turbidite sedimentation. Tectonic configuration of the basin, sediment supply, and relative sea level variation are some of the major factors that control the development and growth of the basin-margin wedge. This dissertation documents two distinct stages of development of the basin-margin wedge at an Eocene active margin, and relates the observed variability in the nature of the shelf-margin, deep-water slope, and basin-floor deposits with these stages. The Tyee Basin in western Oregon was a forearc basin that was filled during late early Eocene and Middle Eocene under greenhouse climatic condition. The sedimentary succession of the Tyee Basin include continental, shallow-marine and deep-water sandstones that are well exposed in Coast Range area of Oregon. The variability observed within the thick and laterally extensive turbidite sandstones of the Tyee Basin led to contrasting depositional models for the Tyee basin in the past. Notably, the submarine ramp model, which provides an alternative model for deepwater coarse clastic deposition, was proposed based on the sedimentary succession of the Tyee Basin. Reconstruction of the clinoformal geometry of the Tyee Basin succession from detailed field data (more than 1000 outcrop locations) and subsurface data reveals two distinct stages of development of this active basin-margin. Each stage has a distinct style of clinoform development and a distinct character of associated sandy deepwater deposits. At the initial stage the basin-margin clinoforms appear to be small (< 250m clinoform height) and strongly progradational, with clinoform topset dominated by the feeder fluvial deposits. At this stage, sandy unconfined (not channelized) turbidite deposits accumulated on the Tyee deepwater slope and extended to the Tyee basin-floor. Large scale sediment conduits on the deepwater slope, in the form of slope channels or canyons, are notably absent in this stage. The second stage is characterized by larger clinoform height (> 500m), higher degree of topset aggradation with repeated fluvio-deltaic cycles on the shelf, and spectacular, sand-rich, well-organized turbidite channels and canyons on the slope. The slope channels active at this stage supplied coarse sediments to the basin-floor to form unusually thick basin-floor fans. The first infill stage represents the embryonic development of a basin-margin wedge on the Tyee continental margin, and could have some similarity with the previously mentioned submarine ramp model. But this was followed by a much longer period of basin-filling when repeated fluvial and shallow-marine cycles formed on the shelf and well-organized turbidite channels were active on the slope supplying sands to the Tyee Basin floor fans. It was concluded that the two stages of development of the basin-margin wedge in the Tyee Basin is controlled largely by the configuration of the basin, that is a result of the prominent topographic/bathymetric features in oceanic basement underlying the sedimentary succession of the Tyee Basin. Tectonically active hinterland and greenhouse climate may have contributed to a relatively high sediment supply to the basin. The relatively small-amplitude sea level variations expected under greenhouse climatic condition of the Early to Middle Eocene are likely to have relatively minor effect on the architecture of the basin-fill. The present work on Tyee Basin builds on earlier research on this basin, but now establishes a ground trothed clinoformal growth model, revises the existing interpretation of sediment transport direction during a major part of the basin-filling history, and demonstrates a two-stage evolution of margin accretion. The observations from the active Tyee Basin was compared and contrasted with a latest Pleistocene sediment wedge on the New Jersey outer shelf. This sediment wedge, developed under icehouse climatic condition, and on a passive margin, was studied using high resolution seismic data (CHIRP). In contrast to the sedimentary succession of the Tyee Basin, the depositional architecture of the sediment wedge on outer New Jersey shelf, which was interpreted as a set of falling stage deltaic clinothems, appears to be strongly controlled by eustatic sea level variation of latest Pleistocene. / text

Active margin

Forearc

Basin-margin wedge

Slope-channel

Basin-floor fan

Delta

Turbidite

Infill

Tyee Basin

Oregon