Lithospheric Fabric in Central North America: the Superior Province and the Mid-Continent Rift

Ola, Oyekunle

21 August 2014

Seismic data from 31 seismic stations, consisting of 16 SPREE (Superior Province Rifting Earthscope Experiment) and 15 TA (Transportable Array) instruments located from 80 - 97W and 41 – 55N were used to measure the lateral variation in the lithospheric fabric beneath the Superior Province and the Mid-Continent Rift (MCR). I made shear wave splitting measurements of SK(K)S phases by using the eigenvector minimization approach of Silver and Chan (1991). Error surfaces for multiple events were stacked in back-azimuthal swaths to examine directional variability. A single anisotropic layer model is sufficient to explain my data. My results show a high split time in the western Superior Province (WSP), very weak splits in the Nipigon Embayment and a moderate split in the eastern Superior. I observed low split times in the Penokean, Yavapai and Matzazal Provinces. A region of very low split is newly detected by this study immediately to the east of Lake Superior. The MCR shows moderate to low split times. There are subtle variations in the direction of the fast shear wave across the study region. The fast directions align with the direction of the absolute plate motion and the direction of tectonic boundaries in most regions. Lateral variation of anisotropy and lithospheric fabric is observed across the study area. The strong fabric observed in the western Superior is truncated to its east and to its south. I interpret southward truncation to be due to the Mid-Continent Rift. My result shows that lithospheric fabric in the Nipigon Embayment (NE) located just east of the WSP has been lost or seriously modified. The NE is interpreted to be an hotspot feature, which may have initiated the MCR. Moreover, the result of this study suggests that the lithosphere in the MCR may have been thinned or modified though not as much as the lithosphere of the NE. The newly discovered localized low split zone northeast of the MCR is similar in split time and extent to the feature in the NE. The relatively weak split in the eastern Superior Province may possibly be attributed to partial loss or modification of preexisting fabric resulting from the Great Meteor hotspot track.

Lithosphere

Mid-Continent Rift

Origin and tectonic evolution of Gondwana Sequence units accreted to the Banda Arc : a structural transect through Central East Timor /

Zobell, Elizabeth A.

January 2007

Thesis (M.S.)--Brigham Young University. Dept. of Geological Sciences, 2007. / Includes bibliographical references (p. 53-59).

Geology, Structural Gondwana (Continent)

Dynamiques du phytoplancton à travers la limite Ordovicien-Silurien aux faibles paléolatitudes (Laurentia - Île d’Anticosti, Québec, Canada ; Baltica - Valga, Estonie) : compléments aux données des hautes latitudes glaciaires du Gondwana / Phytoplankton dynamics across the Ordovician-Silurian boundary at low palaeolatitudes (Laurentia - Anticosti Island, Québec, Canada; Baltica - Valga, Estonia) : an additional contribution to data on the high-latitude glacial areas of Gondwana

Delabroye, Aurélien

26 March 2010

La fin de l’Ordovicien (Hirnantien) est une période charnière de la vie sur Terre. Un ensemble de bouleversements environnementaux, symbolisés par le développement de grandes calottes polaires au Nord-Gondwana, s’accompagne de la première des 'Cinq Grandes Crises Biologiques' du Phanérozoïque. Une révision de la littérature montre que la corrélation directe des évènements biologiques et climatiques avec la base de l'Hirnantien est le résultat de données approximatives. Les dynamiques du microphytoplancton (acritarches) sont alors étudiées au cours de la transition Ordovicien-Silurien. Les données palynologiques publiées, obtenues par analyses de localités de hautes latitudes (Gondwana), sont complétées par l'analyse taxinomique détaillée de 136 échantillons de plateformes carbonatées de faibles latitudes de Laurentia (Île d’Anticosti, Québec) et Baltica (Valga, Estonie). 82 espèces d'acritarches identifiées dans les sections d’Anticosti (52 à Valga) permettent d'établir une nouvelle charte de corrélations biostratigraphiques au sein du bassin d’Anticosti. D'autre part, la répartition paléogéographique du phytoplancton démontre l’existence de deux provinces latitudinales hirnantiennes distinctes (laurentienne/baltique et gondwanienne), expliquant ainsi les difficultés à établir un scénario précis de la crise. Enfin, une dynamique du phytoplancton au sein de ces deux provinces est décrite lors de deux phases glaciaires. La première phase enregistre un « turn-over » des populations concomitant d'une excursion positive des isotopes du carbone. La seconde, plus forte, accompagnée d'une seconde excursion plus marquée, se caractérise par une dynamique de crise avec disparition de nombreux taxa. / The Late Ordovician (Hirnantian) is a transition period in the history of life. Deep environmental perturbations, including the development of a large icecap on North-Gondwana, are marked by the first of the “Big Five Extinctions” of the Phanerozoic. A detailed review of literature data shows that direct correlations between biological and climatic events and the base of the Hirnantian Stage are based on many approximations. Microphytoplankton (acritarchs) biostratigraphy and dynamics across the Ordovician-Silurian boundary are thereafter studied. Published palynological data resulting from the study of high latitudes (Gondwana) localities are completed by a detailed taxonomical analysis of 136 rock samples of low latitude carbonate platforms from Laurentia (Anticosti Island, Québec) and Baltica (Valga, Estonia). Eighty-two acritarch species identified in the Anticosti sections, and 52 from the Valga borehole permit to establish a new biostratigraphic correlative chart in the Anticosti Basin. Moreover, the phytoplankton palaeogeographical distribution shows the existence of two distinct Hirnantian latitudinal phytoplanctonic provinces (Laurentian/Baltic and Gondwanan), accounting for the difficulties to establish a precise scenario of the crisis at a global scale. Finally, phytoplankton dynamics are described in the two regions during two glacial phases. The first one records a turn-over in populations concomitantly to a positive carbon isotope excursion. The second one, larger and paired with a second stronger excursion, is characterized by a crisis marked by the disappearances of numerous taxa.

Limite Ordovicien-Silurien

Baltica (Continent)

An Investigation of Lithospheric Structure and Evolution in Convergent Orogenic Systems using Seismic Receiver Functions and Surface Wave Analysis

Calkins, Josh A

January 2008

Whether by accretion, magmatic addition, or refinement of more mafic lithologies, continental arcs are likely zones for the creation of "average" continental crust with intermediate silica content. This dissertation contains the results of broadband seismic studies carried out in two field areas, an active subduction zone and the remnants of an extinct arc, with the aim of understanding lithospheric evolution at convergent margins. The analytical techniques of receiver function calculation and surface wave tomography are applied to data sets collected above the Andean subduction zone in Chile and western Argentina and in the Coast Mountains Batholith of central British Columbia. We present the first in-depth comparison of receiver functions calculated using the high frequencies available in records of intermediate-depth local earthquakes with those calculated from the lower frequency data in records of larger teleseismic events. The comparison reveals that the lower crust beneath the Western Sierras Pampeanas contains a gradational velocity increase over ~20km above a small velocity step at the Moho. Surface wave tomography confirms the existence of an unusually high velocity anomaly in the mantle above the slab and yields estimates of slab thickness on the order of 50 km. To the south of the flat slab region, we see evidence of active mantle wedge convection above the steep slab, but no evidence of the lithosphere-asthenosphere boundary beneath the subducting Nazca plate. In the Coast Mountains Batholith (CMB), receiver functions image a bright, continuous Moho throughout the study region. Combined with petrologic modeling, the receiver function data point toward convective removal of any ultramafic root that formed beneath the CMB. Low absolute shear wave velocities in the upper mantle resolved via surface wave analysis strengthen the case for root removal beneath the eastern section of the CMB. On the far western edge of the CMB, we find evidence of a partially reformed lithosphere outboard of a major tectonic boundary. These observations shed light on the distillation of felsic to intermediate continental crust from more mafic primary magmas in active subduction zones and the eventual return of the complementary ultramafic residuals to the convecting mantle.

Rayleigh wave amplitudess and the attenuation structure of the earth

Selby, Neil D.

January 1998

No description available.

551

Structural analysis of a potential peri-Gondwanan detachment : George River Suite-Bras d'Or Gneiss contact relations in the Creignish Hills, Cape Breton, Nova Scotia /

Wessel, Zachary R.

January 2004

Thesis (M.S.)--Ohio University, June, 2004. / Includes bibliographical references (p. 88-99).

Structural analysis of a potential peri-Gondwanan detachment George River Suite-Bras d'Or Gneiss contact relations in the Creignish Hills, Cape Breton, Nova Scotia /

Wessel, Zachary R.

January 2004

Thesis (M.S.)--Ohio University, June, 2004. / Title from PDF t.p. Includes bibliographical references (p. 88-99)

Provenance analyses of neoproterozoic/early palaeozoic glacial (?) deposits from southwestern Gondwana

Van Staden, Anelda

07 June 2012

Ph.D. / Louis Agassiz first raised the concept of a global ice age followed by an intriguing history of both proponents and opponents of the idea simultaneously contributing towards the evolution of geological notions up to the present-day ‘Snowball Earth’ model. The causes of glaciation and the sedimentary, geochemical and stratigraphic feedbacks subsequently received renewed interest. Different deposits of possible Neoproterozoic glacial successions were thus selected for detailed provenance analyses in this study. The successions selected are the Puncoviscana Formation on the Pampia Terrane (Northwestern Argentina), the Sierra del Volcán diamictite of the Tandilia System on the Río de la Plata craton (Eastern Argentina), the Kaigas and Numees Formations of the Richtersveld and Gariep areas on the Kalahari craton (Northwest South Africa and Southern Namibia) and the Karoetjes Kop Formation and Swartleikrans Bed of the Bloupoort Formation of the Vanrhynsdorp region on the Kalahari craton (Western South Africa). Diagnostic physicochemical aspects are utilized to ascertain whether the deposits studied are firstly of glacial derivation and, secondly, to constrain the provenance of every deposit. The latter culminate with identification of a regionally or globally significant event. The Sierra del Volcán diamictite is a glacial diamictite with a depositional age younger than 485±2 Ma and is correlatable with the Upper Ordovician Pakhuis Formation (Table Mountain Group) in South Africa. The recognition of a glacial deposit of Upper Ordovician age in eastern Argentina suggests that the Hirnantian ice sheet cover extended from southwest South Africa to eastern Argentina, stretching from the central Paraná basin across into central and northwest Argentina and southern Bolivia. A proximal glacial marine depositional environment is inferred within a subaqueous outwash fan deposited by sediment gravity flow. Periglacial deposits occur in the Pakhuis Formation, suggesting that the ice sheet had retreated with deposition in glacial outwash plains by braided river systems and windblown loess.

Provenance analyses

Glacial deposits

Gondwana (Continent)

Analysis of the tectonic and basin evolution of the seychelles microcontinent during the mesozoic to cenozoic, based on seismic and well data

Mondon, Jean-Luc Andre

January 2014

The Seychelles Microcontinent (SMc) is a fragment of continental lithosphere that experienced multiple phases of rifting and thermal subsidence during its isolation and submergence within the Indian Ocean. Originally part of central Gondwana, along with India and Madagascar, the SMc first emerged during Mesozoic fragmentation of Gondwana (ca. 220 – 180 Ma) along a complex rifted margin. Fragmentation involved three major rift phases, viz.: 1) Middle Triassic – Middle Jurassic (Rift I), associated with the “Karoo rifts” and break-up between [India-Madagascar-Seychelles] and East Africa; 2) Middle Jurassic – Early Cretaceous (Rift II), associated with the rifting and break-up of Madagascar from [India-Seychelles]; 3) Late Cretaceous (Rift III), associated with the rifting and final break-away of the SMc from India. In this study, the tectonic and sedimentary history of the SMc is analysed using 2D seismic reflection datasets and three exploration wells. Seismic to well-log correlations provide a chrono-stratigraphic framework that identifies seven sequences from the Middle Triassic to the Paleogene. This also identified horst and graben structures related to the extensional tectonics and thermal subsidence of this continental fragment. The latter is reflected also in changes of its litho-facies preserved on the SMc, from terrestrial to marine. The oldest sedimentary rocks identified on the SMc are Middle Triassic organic rich claystones (Sequence 7, Rift I), which grade upwards into alternating Upper Triassic sandstones and mudstones (Sequence 6, Rift I) followed by upward coarsening Lower Jurassic mudstones to sandstone units (Sequence 5, Rift I). These sequences are interpreted as lacustrine facies that evolved into fluvial channel migration facies and finally into progradational delta front facies. Sequence 5 is overlain by Middle Jurassic oolitic limestones that grade upwards into organic rich mudstones (Sequence 4, thermal subsidence after Rift I); the latter are interpreted as restricted-marginal marine deposits. Following Sequence 4, separated by a major break-up unconformity (BU), are the Upper Cretaceous open marine deposits comprising limestones, claystones and sandstones, and terminated with basaltic volcanics (ca. 66 Ma) prior to the separation of the SMc from India (Sequence 3, Rift III). This is overlain by the post-rift – thermal subsidence sequences comprising open marine claystones and shelf limestones (Sequence 2) followed by a sequence of shelf limestones (Sequence 1) that form the present carbonate platform, the Seychelles Plateau that lies approximately 200 m below the present sea-level. Backstripping and subsidence analysis quantifies 3 stages of subsidence; Phase A: Slow subsidence (ca. 5-20 m/Ma), from the Middle Jurassic to the Upper Cretaceous that terminated during a major marine transgression during ingression of the Tethys Sea between East Africa and [Madagascar-Seychelles-India]. This created marine conditions and the subsequent deposition of Sequences 4 and 3; Phase B: Accelerated subsidence (ca. 35-60 m/Ma) recorded throughout the Paleocene to the middle Eocene leading to deeper marine conditions and the subsequent deposition of Sequence 2; and Phase C: Reduced subsidence (ca. 10-30 m/Ma) following the interaction between the Carlsberg Ridge and the Reunion hotspot (ca. 55 Ma) that possibly introduced a reduction in subsidence and the subsequent deposition of Sequence 1 as the SMc drifted and thermally subsided to its submerged present location, and is now dominated mainly by marine carbonates. The effects of the Madagascar and Seychelles/India separation (ca. 84 Ma) are not observed in the subsidence analysis, possibly because it involved transcurrent-rotational movement between the two plates over a short period of time.

Sedimentation and deposition

Gondwana (Continent)

Sedimentary basins

Magnetotelluric constraints on the role of fluids in convergent plate boundaries

Rippe, Dennis

Unknown Date

No description available.

Canadian Cordillera

Tibetan Plateau

Subduction zone

Continent-continent collision

Magnetotellurics

Rheology

Dehydration melting

Channel flow