The Relationship of Laramide Stocks to Regional Structure in Central Arizona

Balla, John Coleman

January 1972

The area of this study is a northeast trending zone which is approximately ninety miles long, extending from Casa Grande to Globe, Arizona. A number of porphyry copper deposits and barren Laramide stocks occur within this zone. Geological mapping of the various Laramide granitic stocks shows that all of the stocks are composite, epizonal granitic stocks, which are all elongate in a N45°E to N80°E direction. Sulfide bearing veins also trend N45°E to N80°E. The configuration of the stocks defines the structural framework into which they were intruded. The consistent elongation of the granitic stocks shows that the stocks were intruded into a series of parallel, regional faults that trend approximately N60°E to N80°E. Isotopic dating of the stocks shows that they become progressively younger from west to east. Typical isotopic ages are 71 m.y. on the west portion of the zone, and 61 m.y. on the east portion. The porphyry copper deposits also show a trend of decreasing age from west to east. The granitic Laramide stocks are localized where the N45°E to N80°E regional faults intersect the Precambrian granite-Pinal Schist contact. In some cases the regional faults are parallel to the Precambrian granite-Pinal Schist contact, in which case the Laramide stocks are parallel to the contact. The Laramide quartz diorite stocks only occur along the "San Pedro hinge line" and farther to the east. Although the individual quartz diorite stocks are aligned in an east-northeast direction, the overall geographical trend of the quartz diorite is north-northwest. The quartz diorite stocks may also become progressively younger proceeding to the east. The defining of the regional faults or lineaments, based upon the orientation of the Laramide granitic stocks, permits a rather precise projection of these lineaments into areas of complete post-mineral rocks. This allows a large area of post-mineral rocks to be reduced to a rather small area, where exploration for porphyry copper deposits can be intensified.

Arizona

central

correlation

intrusions

occurrence

patterns

regional

stocks

structural geology

structure

tectonics

United States

Tectonic Geomorphology and Paleoseismicity of the Northern Esk Fault, North Canterbury, New Zealand

Noble, Duncan Paul

January 2011

Geomorphic, structural and chronological data are used to establish the late Quaternary paleoseismicity of the active dextral-oblique Northern Esk Fault in North Canterbury, New Zealand. Detailed field mapping of the preserved c. 35 km of surface traces between the Hurunui River and Ashley Head reveals variations in strike ranging from 005° to 057°. Along with kinematic data collected from fault plane striae and offset geomorphic markers along the length of the fault these variations are used to distinguish six structural subsections of the main trace, four dextral-reverse and two dextral-normal. Displacements of geomorphic markers such as minor streams and ridges are measured using differential GPS and rangefinder equipment to reveal lateral offsets ranging from 3.4 to 23.7 m and vertical offsets ranging from < 1 to 13.5 m. Characteristic single event displacements of c. 5 m and c. 2 m have been calculated for strike-slip and reverse sections respectively. The use of fault scaling relationships reveals an anomalously high displacement to surface rupture length ratio when compared to global data sets. Fault scaling relationships based on width limited ruptures and magnitude probabilities from point measurements of displacement imply earthquake magnitudes of Mw 7.0 to 7.5. Optically Stimulated Luminescence (OSL) ages from displaced Holocene alluvial terraces at the northern extent of the active trace along with OSL and radiocarbon samples of the central sections constrain the timing of the last two surface rupturing events (11.15 ±1.65 and 3.5 ± 2.8 ka) and suggest a recurrence interval of c. 5612 ± 445 years and late Quaternary reverse and dextral slip rates of c. 0.31 mm/yr and 0.82 mm/yr respectively. The results of this study show that the Northern Esk Fault accommodates an important component of the c. 0.7 – 2 mm/yr of unresolved strain across the plate boundary within the North Canterbury region and affirm the Esk Fault as a source of potentially damaging ground shaking in the Canterbury region.

Esk Fault

Tectonics

Seismicity

Paleoseimicity

North Canterbury

Geomorphology

Optically Stimulated Luminescence

Radiocarbon

Southward propagation of the Marlborough Fault System: Fault linkage and blind faults in North Canterbury

Mittelstaedt, Jana

January 2011

Geomorphological and paleoseismic studies provide insight into the fault geometry and kinematics of a series of dextral northeast striking faults, including the Porters Pass, Hawdon, Bullock Hill, and Esk faults, in the South Island of New Zealand. These faults show post-glacial offsets that are significantly larger than predicted from co-seismic displacement - surface rupture length regressions derived from empirical relationships. Geomorphological mapping reveals slip rates as high as 9 mm/year for the Hawdon fault and Bullock Hill fault over an expected fault length of c. 140 km. Surface expressions of some parts of the studied faults are obscured by glacial gravels, indicating that blind faults are present in parts of the Sourthern Alps and may be the source for a component of a reported slip deficit in North Canterbury. Concluding from comparing scaling relationship results for the individual faults I hypothesize that the Porters Pass, Hawdon, Bullock Hill and Esk faults are segments of an incipient fault system that stretches from the western tip of the Porters Pass fault to the Hope fault, east of Hanmer Springs. Considering the location, similar strike and dextral deformation mode, I suggest that this 140 km long dextral strike-slip fault system marks the southernmost extension of the Marlborough Fault System resulting from the ongoing southward propagation of the Pacific-Australian plate boundary in New Zealand's South Island.

Esk Fault

Hawdon Fault

Bullock Hill Fault

Marlborough Fault System

active tectonics

Analogue modelling of strike-slip surface ruptures: Implications for Greendale Fault mechanics and paleoseismology

Sasnett, Peri Jordan

January 2013

Analogue modelling of strike-slip faulting provides insight into the development and behaviour of surface ruptures with accumulated slip, with relevance for understanding how information recorded in paleoseismic trenches relates to the earthquake behaviour of active faults. Patterns of surface deformation were investigated in analogue experiments using cohesive and non-cohesive granular materials above planar strike-slip basement faults. Surface deformation during the experiments was monitored by 3D PIV (particle image velocimetry) and 2D time lapse photography. Analysis focused on fault zone morphology and development, as well as the relationship of the models to surface deformation observed at the Greendale Fault that resulted from the 2010 Darfield earthquake. Complex rupture patterns with similar characteristics to the Greendale Fault (e.g. en echelon fractures, Riedel shears, pop-up structures, etc.) can be generated by a simple fault plane of uniform dip, slip, and frictional properties. The specific structures and the style of their development are determined by the properties of the overburden and the nature of the material surface. The width of the zone of distributed deformation correlates closely with sediment thickness, while the width of discrete fracturing is controlled by the material properties as well as the thickness of the overburden. The overall deformation zone width increases with the growth of initial, oblique fractures and subsequently narrows with time as strain localizes onto discrete fractures parallel to the underlying basement fault. Mapping the evolution of fracture patterns with progressive strain reveals that Riedel shears, striking at 90-120° (underlying fault strike = 90°) are more frequently reactivated during multiple earthquake cycles, and are thus most likely to provide reliable paleoseismic records. This will help identify suitable locations for paleoseismic trenches and interpret trench records on the Greendale Fault and other active, strike-slip faults in analogous geologic settings. These results also highlight the tendency of trenching studies on faults of this type to underestimate the number and displacement of previous ruptures, which potentially leads to an underestimate of the magnitude potential and recurrence interval of paleoearthquakes.

analogue modelling

surface rupture morphology

paleoseismology

Greendale Fault

active tectonics

neotectonics

PIV

PROVENANCE OF THE NEOPROTEROZOIC OCOEE SUPERGROUP, EASTERN GREAT SMOKY MOUNTAINS

Chakraborty, Suvankar

01 January 2010

The Ocoee Supergroup is a sequence of Neoproterozoic, immature, continental rift facies clastic sediments. Potential source rocks were tested by analyzing modes of detrital framework minerals, detrital mineral chemistry, whole rock geochemistry and detrital zircon U/Pb geochronology by LA-ICP-MS for Ocoee siltstone-sandstone dominated formations. Ocoee units are arkosic to subarkosic siltstones/sandstones, and ternary tectonic discrimination diagrams confirm a continental basement uplift source. Alkali feldspar predominates over plagioclase feldspar. Detrital feldspar compositions of Ocoee sediments as a group are similar to feldspar in local basement granitic rocks except for high-Ca plagioclase grains present locally in basement granitic rocks. The high alkali content of the detrital feldspars in the Ocoee Supergroup is consistent with derivation from an A-type granite source terrane. Normative Q-A-P values, calculated from wholerock chemistry, and trace element diagrams are also supportive of an A-type granite source for these rocks. The siltstones and sandstones of the Snowbird Group contain high abundances of heavy minerals (zircon, titanite, ilmenite, epidote and apatite), which are dispersed among other detrital grains and as concentrations of heavy minerals in discrete laminae. ZTR index and titanite mineral chemistry suggest a granitic source for these sediments. Detrital zircon geochronology in Ocoee sediments indicates a dominantly Grenville (1000 to 1300 Ma) source for these sediments. The youngest zircon age in the basal Ocoee Wading Branch Formation (639±8 Ma) is related to rift magmatism and provides a minimum depositional age for the Ocoee Supergroup.

Ocoee Supergroup

Geochronology

Geochemistry

Mineral chemistry

Grenville age

Oil, Gas, and Energy

Sedimentology

Tectonics and Structure

BEDROCK MAPPING OF THE WINCHENDON (1:25,000) QUADRANGLE (MA-NH): EVIDENCE FOR DISCONTINOUS DEFORMATION ALONG THE BRONSON HILL-CENTRAL MAINE BOUNDARY ZONE

O'Brien, Timothy M.

01 January 2009

Bedrock geology of the Winchendon quadrangle is divided into two zones based on structures and lithology. The eastern zone consists of tightly folded Silurian Rangeley and Paxton metasediments and pegmatites. Planar, NNE-SSW striking, W dipping foliations are characterized by alternating phyllosilicate-rich and leucosome layers. Fold axes of tight to isoclinal upright and recumbent folding are parallel to SSW-NNE shallowly plunging sillimanite, quartz and muscovite lineations. In the western zone Rangeley schists were intruded by Devonian Hardwick and Coys Hill and Fitzwilliam plutons. Planar NNE-SSW striking foliations dip shallowly to steeply west. Fold axes of tight-to-isoclinal asymmetric to recumbent folds plunge shallowly to steeply SSW, parallel to elongate quartz and feldspar lineations. Fabrics in both portions developed in by greenschist facies mineral assemblages Asymmetric porphyroclasts and S-C/C’ fabrics from both areas display dextral asymmetry. Lateral extrusion as the result of pure-shear dominated E-W shortening and N-S extension is recorded by structures that exhibit strong contractional strains, accompanied by stretching fabrics. A 2-3 kilometer wide belt of deformation named the Bronson Hill-Central Maine Boundary Zone (BHCMBZ) correlates with the Conant Brook Shear Zone. This creates a zone of deformation that widens to the north and separates Ordovician plutons of the Bronson Hill zone from units of the Central Maine zone. North of Winchendon, retrograde deformation is absent and Acadian metamorphism and structures are preserved. This creates an inconsistency in along-strike deformation the length of the inferred terrane boundary. A larger terrane, composed of the Bronson Hill and Central Maine zones is proposed to account for the discontinuous deformation along strike.

Geology

PALEOSEISMIC AND STRUCTURAL CHARACTERIZATION OF THE HINES CREEK FAULT: DENALI NATIONAL PARK AND PRESERVE, ALASKA

Federschmidt, Sara E

01 January 2014

The Hines Creek fault (HCF) is a Holocene-active fault in central Alaska. Its trace has been mapped several times, but data on the history of fault displacement is scarce. As a major crustal-scale geologic boundary with uncertain Quaternary tectonic activity, it is a priority for more to be known about the activity of this fault to better understand the hazards it presents to the Denali National Park and Preserve and Alaskan infrastructure. This study characterizes the late Quaternary activity of the HCF through surficial geologic mapping and paleoseismic investigations. Mapping revealed a very steep (~84°-88° apparent dip), north dipping fault plane and measurements from offset Pleistocene outwash terraces revealed south side-down vertical offsets of up to 12 m, indicating a steeply dipping reverse fault. Three paleoseismic trenches excavated across the fault trace provided a record of seismic activity and hold evidence for at least four prehistoric earthquakes in the last 2 ka. Slip rate calculations estimate movement on the HCF to be between 0.6mm yr-1 and1.2 mm yr-1. The active trace of the HCF follows the southern margin of the tectonically active Mount Healy anticline, suggesting a kinematic linkage between the fault that underlies this anticline and the HCF.

Paleoseismology

neotectonics

coseismic fissures

Alaska Range

Hines Creek fault

Geology

Geomorphology

Tectonics and Structure

The longitudinal treatment and structure of plate tectonics in introductory college-level physical geology textbooks : 1974-2005

Fowler, Philip A.

January 2005

The objective of this study was to determine if trends were present in the longitudinal treatment of concepts of plate tectonics in introductory college-level physical geology textbooks. In addition, a method was designed to convey the structure of these concepts of plate tectonics by determining the location in the textbook where they occur.Eighteen textbooks were selected from the time period of 1975 through 2004. The total narrative area was determined by measuring the height and width of each column of text in each textbook. Individual concepts of plate tectonics were determined using the constant comparative method. Nine concepts were identified. The treatment of each concept was expressed as a concept's percentage of the textbook's total narrative area. The structure of plate tectonics in each textbook was determined by creating scatterplots and pie graphs of the location within the text and the area devoted to each concept. Furthermore, a measure of the structure of the textbook over the study period was determined by comparing the proportion of chapters containing concepts of plate tectonics with the publication date.A strong positive correlation (r=.638) was found between the treatment of the theory of plate tectonics and the publication date of the textbook. This correlation was significant to the 0.01 level. Two of the nine identified concepts of plate tectonics were also found to have significant correlations.Similarly, a strong positive correlation was found between the proportion of chapters containing concepts of plate tectonics and the publication date. Thus, concepts of plate tectonics are found in more chapters in textbooks published during the latter parts of the study period.A concern arising from this study is the treatment of the concept identified as "The evidence for and the development of plate tectonics." This is the only identified concept of plate tectonics that showed a marked decrease during the study period. Furthermore, this concept corresponds with other studies that found many of America's textbooks reporting the end results of science while omitting the nature of science. / Department of Geology

Tectonic motions and earthquake deformation in Greece from GPS measurements

Clarke, Peter John

January 1996

Sites in a 66-station geodetic network in central Greece have been occupied up to six times since 1989 using GPS surveying, and accurate positions have been computed using fiducially-improved or precise orbits. Site velocities are calculated under the assumption that they are constant with time, after correcting for co-seismic effects, and that the position of the fixed base station (and hence the entire network) may be subject to small errors. Low-order polynomial expressions do not fit the velocity field well. The pattern of observed strain closely resembles that derived from independent geodetic observations made over a hundred-year time-scale. Significant geodetic strain is observed across the Gulf of Korinthos, even after the co-seismic displacement field of the Ms=6.2 1995 Egion earthquake has been removed by forward modelling. Geodetic strain is higher in the western than eastern Gulf, in contrast to the seismic strain which is similar throughout. Seismic strain matches geodetic strain in the east, but a significant deficit of seismic moment exists in the west which may represent a high earthquake hazard in the medium term. The Ms=6.6 1995 Grevena earthquake struck a previously seismically quiet region well covered by a recent triangulation / trilateration survey. Ninety-one points from this network were reoccupied with GPS immediately after the earthquake, and site displacements computed. To invert for the earthquake source parameters from the geodetic displacement field, a novel inversion scheme is used which combines the Monte-Carlo and simplex approaches. A priori parameters are not required, even though the inverse problem is strongly nonlinear. The resulting focal mechanism agrees well with the global CMT solution and locally observed aftershocks, but implies a significantly higher scalar moment than do seismological studies. A network for observing post-seismic deformation has been established, which in view of the low background seismicity seems likely to provide significant results.

551.21

Marine geophysical study of the Eurasian-African plate boundary in the vicinity of Gorringe Bank

Hayward, Nathan

January 1996

The Gorringe Bank region is located at the eastern end of the Azores-Gibraltar plate boundary, which plate kinematic studies show to progressively change from extension at the Azores, through pure right lateral strike slip at the Gloria fault to compression at Gibraltar. The region is dominated by high relief (4-5 km), highly deformed, uncompensated, ENE-WSW trending seamounts and intervening abyssal plains with basin sediment thicknesses in excess of 4 km and minimal surface deformation. Gorringe Bank, which was formed by overthrusting of the African plate upon the Eurasian plate at about 10 Ma along the plate boundary, is supported in part by exure of the Eurasian plate, as indicated by pre-loading sediments and basement to the north which are tilted towards Gorringe Bank. Broken plate models show the Eurasian plate to have an elastic thickness of about 35 km which is in agreement with that expected for the crustal age (130-135 Ma) at the time of loading. Coral Patch Ridge was formed by a combination of thrust faulting and whole crustal buckling resulting from the past 20 Ma compression and was partially uplifted before deposition of an olistostrome in the Middle Miocene. Recent compressional deformation is distributed over a wide region, as indicated by the dispersed shallow seismicity and has a trend which rotates from approximately N45oE to N70oE from west to east across the region, near perpendicular to westward verging plate motion vectors. The majority of extensional and strike-slip deformation is explained by a regional strike-slip strain ellipse model, including an antithetic NNE-SSW strike slip fault between Gettysburg and Hirondelle seamounts which marks the boundary between the Eastern and Western Horseshoe Basins. Isostatic models for the Madeira-Tore Rise, which initially formed at the Mid Atlantic Ridge, give an elastic thickness of approximately 15 km indicating that significant material was added to the Rise as it moved away from the Ridge.

551.21