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11	Subsurface Facies Aanalysis of the Cambrian Conasauga Formation and Kerbel Formation in East - Central Ohio Banjade, Bharat 29 November 2011 (has links) No description available. Geology Petroleum Geology Sedimentary Geology Conasauga Formation Kerbel Formation Depositional Environment Facies Analysis Cambrian Geology Transgression
12	Depositional environment and taphonomy of some fossil vertebrate occurrences in Lower Permian redbeds in Archer County, Texas Sander, Paul Martin 04 February 2013 (has links) The Lower Permian Admiral Formation redbeds in north-central Texas are famous for their well-studied vertebrate fauna. Taphonomical and paleoecological aspects, however, are inadequately understood. The prerequisite for taphonomical interpretations is an analysis of the depositional environments. Low relief and low regional dip expose extensive paleoslopes in western Archer County. Three major depositional systems may be recognized: a fine-grained meanderbelt, a low sinuosity fine-grained fluvial system, and a tidal flat. The small scale of the sedimentation (average sandstone thickness 1. 5 m) is remarkable. Four types of vertebrate occurrences can be distinguished: Type 1: Mass death bonebeds are situated in a floodbasin facies comprised of gray and red mudstones with abundant Psaronius roots (a swamp-dwelling tree fern) which is associated with the fluvial systems. Such basins were covered by a dense swamp forest with a high diversity of vertebrates. This type is exemplified by the Geraldine Bonebed, which has yielded at least 45 partly articulated skeletons representing 4 genera of tetrapods, and remains of another 8 vertebrate taxa. The bones were found on a layer of fern, seed fern, and conifer foliage and wood. This occurrence was formed by a single catastrophic event, possibly a forest fire, which drove the animals of the swamp forest into a pond, where they died of suffocation and were concentrated into a bonebed by physical processes (wind). Type 2: Lag bonebeds, situated on the landward margin of tidal flat environments, are represented by the Rattlesnake Canyon Bonebed which consists mainly of a calcareous concretion conglomerate, which contains fragmentary bone, serpulid worm colonies (brackish water!), and calamitelean wood. The diversity of forms represented by articulated material is low. The ubiquitous predator Dimetrodon and an amphibian, Trimerorachis, which tolerates brackish water, are common. This type was deposited as lag in a storm washover deposit. Type 3: Ponds (abandoned channels, etc.) which contained a fauna dominated by aquatic forms (the fishes Xenacanthus and Ectosteorachis, and the amphibian Archeria) were gradually filled by fine-grained sediment and organic debris (vertebrates, plants). These oxbow lakes were probably rimmed by stands of Calamites. Four examples are described. Type 4: Single, complete skeletons examplified here by Diadectes are occasionally found in red floodplain mudstones. / text Lower Permian Admiral Formation Archer County, Texas Redbeds Fossil vertebrate Depositional environment Taphonomy Paleontology--Texas--Archer County Paleontology--Permian Vertebrates, Fossil
13	Lithofacies, depositional environments, and sequence stratigraphy of the Pennsylvanian (Morrowan-Atokan) Marble Falls Formation, Central Texas Wood, Stephanie Grace 01 November 2013 (has links) The Pennsylvanian Marble Falls Formation in the Llano Uplift region of the southern Fort Worth Basin (Central Texas) is a Morrowan-Atokan mixed carbonate-siliciclastic unit whose deposition was influenced by icehouse glacioeustatic sea-level fluctuations and foreland basin tectonics. Previous interpretations of the Marble Falls Formation focused on outcrop data at the fringes of the Llano Uplift. This study uses a series of 21 cores to create a facies architectural model, depositional environmental interpretation, and regional sequence stratigraphic framework. On the basis of core data, the study area is interpreted to have been deposited in a ramp setting with a shallower water upper ramp area to the south and a deeper water basin setting to the north. Analysis of cores and thin sections identified 14 inner ramp to basin facies. Dominant facies are: (1) burrowed sponge spicule packstone, (2) algal grain-dominated packstone to grainstone, (3) skeletal foraminiferal wackestone, and (4) argillaceous mudstone to clay shale. Facies stacking patterns were correlated and combined with chemostratigraphic data to improve interpretations of the unit’s depositional history and form an integrated regional model. The Marble Falls section was deposited during Pennsylvanian icehouse times in a part of the Fort Worth Basin with active horst and graben structures developing in response to the Ouachita Orogeny. The resulting depositional cycles reflect high-frequency sea-level fluctuations and are divided into 3 sequences. Sequence 1 represents aggradational ramp deposition truncated by a major glacioeustatic sea-level fall near the Morrowan-Atokan boundary (SB1). This fall shifted accommodation basinward and previously distal areas were sites of carbonate HST in Sequence 2 deposition following a short TST phase. Sequence 3 represents the final phase of carbonate accumulation that was diachronously drowned by Smithwick siliciclastics enhanced by horst and graben faulting. These findings contribute to our understanding of the depositional response to glacioeustatic sea-level changes during the Pennsylvanian and can also form the basis for constructing a sedimentological and facies analog for Morrowan to Atokan shallow- to deepwater carbonates in the Permian Basin and the northern Fort Worth Basin. / text Pennsylvanian Morrowan Atokan Mixed carbonate-siliciclastics Marble Falls Carbonate ramp Icehouse glacioeustasy Central Texas Llano Uplift Algal mounds Sponge spicule Sequence stratigraphy Depositional environment
14	Geologically-based permeability anisotropy estimates for tidally-influenced reservoir analogs using lidar-derived, quantitative shale character data Burton, Darrin 16 June 2011 (has links) The principle source of heterogeneity affecting flow behavior in conventional clastic reservoirs is discontinuous, low-permeability mudstone beds and laminae (shales). Simple ‘streamline’ models have been developed which relate permeability anisotropy (kv/kh ) at the reservoir scale to shale geometry, fraction, and vertical frequency. A limitation of these models, especially for tidally-influenced reservoirs, is the lack of quantitative geologic inputs. While qualitative models exist that predict shale character in tidally-influenced environments (with the largest shales being deposited near the turbidity maximum in estuaries, and in the prodelta-delta front), little quantitative shale character data is available. The purpose of this dissertation is to collect quantitative data to test hypothetical relationships between depositional environment and shale character and to use this data to make geologically-based estimates of for different reservoir elements. For this study, high-resolution, lidar point-clouds were used to measure shale length, thickness, and frequency. This dissertation reports a novel method for using distance-corrected lidar intensity returns to distinguish sandstone and mudstone lithology. Lidar spectral and spatial data, photo panels, and outcrop measurements were used to map and quantify shale character. Detailed shale characteristics were measured from four different tidally-influenced reservoir analogs: estuarine point bar (McMurray Formation, Alberta, Canada), tidal sand ridge (Tocito Sandstone, New Mexico), and unconfined and confined tidal bars (Sego Sandstone, Utah). Estuarine point bars have long (l=67.8 m) shales that are thick and frequent relative to the other units. Tidal sand ridges have short (l=8.6 m dip orientation) shales that are thin and frequent. Confined tidal bars contain shales that are thin, infrequent, and anisotropic, averaging 16.3 m in length (dip orientation). Unconfined tidal bars contain nearly equidimensional (l=18.6 m dip orientation) shales with moderate thicknesses and vertical frequency. The observed shale geometries agree well with conceptual models for tidal environments. The unique shale character of each unit results in a different distribution of estimated . The average estimated kv/kh values for each reservoir element are: 8.2*10^4 for estuarine point bars, 0.038 for confined tidal bars, 0.004 for unconfined tidal bars, and 0.011 for tidal sand ridges. / text Lidar Tidally-influenced reservoirs Shale Depositional environment Shale characterization Permeability anisotropy McMurray Formation Sego Sandstone Tocito Sandstone Tidal bars Tidal sand ridges
15	The Conodont Biostratigraphy of the Black Prince Limestone (Pennsylvanian) of Southeastern Arizona Barrie, Kathleen Ann January 1975 (has links) The Black Prince Limestone of southeastern Arizona has been assigned to the Morrowan on the basis of several long-ranging fossils. Since these were not especially diagnostic, the exact time represented by the Black Prince within the Morrowan was uncertain. To date the Black Prince more precisely, six sections were systematically sampled for conodonts. The condonts found, especially Neognathodus bassleri, Rachistognathus muricatus, Idiognathoides convexus, and Spathoqnathodus coloradoensis, indicate a middle Morrowan to early Derryan age for the Black Prince in the study area. Four conodont zones can be recognized: the Neognathodus bassleri Zone, the Idiognathodus sinuosis.- Streptognathodus anteeccentricus Zone , the Idiognathoides convexus Zone, and the Spathognathodus coloradoensis-Neognathodus columbiensis Zone. These zones compare favorably with the zonation previously established in the type Morrowan. This biostratigraphic evidence suggests that the hiatus between the Black Prince and Horquilla Limestones increases in magnitude from southeastern to south-central Arizona. The Black Prince represents a sequence of tidal flat and shallow subtidal carbonate deposits. Mudstones and sparsely fossiliferous wackestones with low fossil diversity and abundance characterize the tidal-flat facies. Grainstones, packstones, and fossiliferous wackestones with high fossil diversity and abundance characterize the shallow subtidal facies. Arizona biostratigraphy Black Prince Limestone carbonate rocks Carboniferous clastic rocks Conodonta depositional environment Horquilla Limestone Idiognathoides Lower Pennsylvanian microfossils Morrowan mudstone Neognathodus Paleozoic Pennsylvanian Rachistognathus sedimentary rocks southeast Spathognathodus stratigraphy subtidal tidal flats United States zoning
16	Environnement sédimentaire, stratigraphie séquentielle et paléogéographie du Paléozoique de succession pré-Khuff dans le sud de l'Iran (Zagros et le Golfe Persique) / Sedimentary environment, sequence stratigraphy and paleogeography of Paleozoic Pre-Khuff succession in southern Iran (Zagros and Persian Gulf) Asghari, Afshin 15 December 2014 (has links) Au cours du Précambrien et du Paléozoïque, la zone Zagros faisait partie de la plate-forme Arabe. La succession Paléozoïque du Zagros s’étend du Cambrien au Permien. La zone d'étude se situe entre le Lurestan et le Fars au sud et le Golfe Persique. Au Paléozoïque, dans le secteur du Zagros, la série stratigraphique comprend quatre séquences de second ordre (ou cycles tectonostratigraphiques) séparées par d’importantes discordances. L’eustatisme est le principal facteur déterminant les changements d’espace d’accommodation, même si localement dans l'Ouest du Haut Zagros, le rôle de la tectonique régionale et des mouvements diapririques est important. Le premier cycle (Ordovicien) est composé des Fomrations Seyahou (Floien-Katien) et Dargaz (Hirnantien). Il enregistre une évolution depuis des milieux profonds à peu profonds de plate-forme siliciclastique. La Formation Seyahou est découpée en sept séquences de troisième ordre et la Formation Dargaz correspondant à des dépôts glaciogènes comprends deux séquences de troisième ordre. Le deuxième cycle (Silurien inférieur) correspond à la Formation Sarchahan. Il est caractérisé des environnements marins peu profonds à profonds comprenant des marnes riches en matière organique. Il est composé par deux séquences de dépôt de troisième ordre. Localement à Kuh e Gahkum, la base de cette Formation enregistre des dépôts peu profonds de transition continental-marin dont la présence est attribuée à la mise en place d’un diapir dans le secteur. Le troisième cycle (Dévonien) correspond à la Formation Zakeen. Les dépôts évoluent depuis des environnements continentaux à marins. La fin du Dévonien est marqué par des environnements marins carbonatés dans le sud de la région du Fars et dans le Golfe Persique. Il est divisé en trois séquence de troisième ordre. L’absence de la Formation Zakeen à Kuh e Surmeh et Kuh e Siah, et sa présence dans les régions voisines (Naura, West Agar, etc ...), suggèrent une activité diapirique, expliquant l’érosion locale des séries sédimentaires. Le dernier cycle de la succession pré-khuff dans la zone d'étude correspond à la Formation Faraghan du Permien inférieur. Il surmonte une discontinuité attribué au jeu de l'orogenèse Hercynienne et est déposé dans toute la région du Zagros et dans le Golfe Persique. La Formation Faraghan correspond à des environnements de plaine côtière à marins et est divisé en trois séquences de troisième ordre.La succession du Paléozoïque est marquée par plusieurs discordances majeures. Elles résultent de: (i) variations majeures du niveau marin en lien avec des variations glacioeustatiques comme pour le cas de la glaciation Hirnantien à la fin de l’Ordovicien et celle du Carbonifère; (ii) Un soulèvement du Moyen-Orient à la fin du Silurien associé aux mouvements épeirogéniques et à une baisse importante du niveau de la mer; et (iii) l'orogenèse Hercynienne allant de la fin du Dévonien à Carbonifère. Localement, les discordances peuvent aussi s’expliquer par le jeu de remontée diapirique induisant une érosion locale, comme c’est le cas dans les secteurs de Kuh e Surmeh et de Kuh e Gakhum pour des periodes de temps différentes. / During the Precambrian and trough the Palaeozoic, the Zagros area was part of the Arabian platform (Beydon, 1993). The Palaeozoic succession of the Zagros extends from Cambrian to well-developed Permian deposits. The study area ranges from the Lurestan to Southern Fars onshore and to the Persian Gulf offshore wells. From Ordovician to Early Permian Palaeozoic succession of the Zagros area comprises four second-order tectonostratigraphic depositional cycles separated by major unconformities. Eustatic sea-level variation is the main controlling factor for accommodation space changes, whereas in West High Zagros and Kuh e Gahkum, the role of regional and salt tectonic activities may be also important. The first cycle (Ordovician) is composed of the Seyahou (Floian-Katian) and Dargaz (Hirnantian) Formations. They are characterized by deep- to shallow-water (offshore to shoreface) siliciclastic deposits. The Seyahou Formation contains seven 3rd-order depositional sequences. The glaciogenic Dargaz Formation consists of one 3rd- order sequence. The second cycle (Early Silurian) corresponds to the Sarchahan Formation is composed of two 3rd-order depositional sequences. They are characterized by deep-marine offshore to upper offshore environments. Locally in Kuh e Gahkum the base of the Formation presented continental fan delta deposits due to the salt tectonic activity.The third cycle (Devonian) corresponds to the Zakeen Formation and divided in three 3rd-order depositional sequences. It started with the deposition of continental to near-shore marine clastic deposits. In Late Devonian, it evolved to carbonate marine deposits in the south of Fars area and the Persian Gulf. The lack of Zakeen Formation in Kuh e Surmeh and Kuh e Siah, and is presence in neighboring areas (Naura, Aghar, etc…), suggests structural salt plug activities (Jahani, 2008). This megasequence is capped by a major unconformity related to the Hercynian orogeny.The last deepening-upward cycle of the Pre-khuff succession in the study area is the Early Permian Faraghan Formation. It capped the Hercynian orogeny and deposited throughout the Zagros area from Lurestan (west) to Bandar Abbas (East) areas as well as in Persian Gulf. The Faraghan Formation divided into three 3rd-order depositional sequences and deposited in coastal plain to shallow-marin near-shore environment. Basinward, in the deeper part (e.g. Kuh e Faraghan), they are replaced by marine upper offshore deposits. The Palaeozoic succession is marked by several major unconformities associated with hiatus. They resulted from: (i) major sea level drops at the end of the Ordovician related to the Hirnantian glaciation (Ghavidel Syooki et al., 2011) and of during the Carboniferous related to the southern Hemisphere glaciation (Golonka, 2000); (ii) An uplift of the Middle East area at the end of the Silurian associated with epeirogenic movements (Ala et al., 1980; Berberian and King, 1981; Al-Sharhan and Nairn, 1997) and a major sea level drop at the end of Silurian (Al-Husseini, 1991,1992; Sharland et al., 2001; Konert et al., 2001; Haq and Al-Qahtani, 2005); and (iii) impact of the Hercynian orogeny spanning from the Late Devonian up to the Carboniferous (Al-Hosseini, 1992; Sharland et al., 2001; Konert et al., 2001, Faqira et al., 2009). Paléozoïque Pré-Khuff La région de Zagros Iran Plate Arabique Faciès sédimentaires Environnement de dépôt Stratigraphie séquentielle Paléogéographie Paléoclimats Palaeozoic Pre-Khuff Zagros area Iran Arabian Plate Sedimentary facies Depositional environment Sequence stratigraphy Palaeogeography Palaeoclimate 550 560
17	線型モデルによる砕屑性堆積物形成過程の解析水谷, 伸治郎 03 1900 (has links) 科学研究費補助金研究種目:一般研究(C) 課題番号:03640640 研究代表者:水谷伸治郎研究期間:1991-1992年度粒度組成形成環境円磨度シルト質砂粒一次線型モデル混合過程混合相確率紙 Size composition probability paper roundness mixing process depositional environment mixed material 確立紙 silt grain linear model
18	Paleocurrents and Depositional Environments of the Dakota Group (Cretaceous), San Miguel County, New Mexico Bejnar, Craig Russel January 1975 (has links) The Dakota Group surrounding Las Vegas, New Mexico, consists of three units: 1) a basal, predominately trough cross-stratified, conglomeratic sandstone, 2) middle intercalated, thin-bedded sandstone and carbonaceous shale, and 3) upper, predominately tabular-planar cross-stratified, sandstone containing trace fossils. These units represent, respectively, 1) a fluvial piedmont plain, 2) fluvial coastal plain, and 3) a beach, littoral, and shallow marine complex. The cross-stratification in the lower sandstone unit indicates an easterly paleoslope. The cross-stratification in the upper sandstone unit has a bimodal distribution almost at right angles to the paleoslope, suggesting deposition by longshore currents. The standard deviation of the cross-stratification in the lower sandstone unit of 78° is typical of fluvial deposits. The standard deviation in the upper sandstone unit of 97° indicates a marine origin. algae bedding plane irregularities biostratigraphy clastic rocks Cretaceous cross-stratification Dakota Formation depositional environment environment environmental analysis indicators lithostratigraphy marine Mesozoic microfossils Mora County New Mexico nannofossils nearshore New Mexico northeast paleocurrents palynomorphs planar bedding structures Plantae provenance ripple marks San Miguel County New Mexico sandstone sedimentary petrology sedimentary rocks sedimentary structures sedimentation shale shallow stratigraphy streams terrigenous thallophytes United States
19	Geobiology of bituminous carbonates from the Ediacaran Shibantan Member (Dengying Formation, South China) Duda, Jan-Peter 20 August 2014 (has links) No description available. 910 550
20	Stratigraphy and Sedimentology of the Bisbee Group in the Whetstone Mountains, Pima and Cochise Counties, Southeastern Arizona Archibald, Lawrence Eben January 1982 (has links) The Aptian-Santonian(?) Bisbee Group in the Whetstone Mountains comprises 2375 m of clastic sedimentary rocks and limestones. The basal Glance Conglomerate unconformably overlies the Pennsylvanian-Permian Naco Group. It consists of limestone conglomerates which were deposited in proximal alluvial fan environments. The superadjacent Willow Canyon Formation contains finer grained rocks which were deposited in the distal portions of alluvial fans. The lacustrine limestones in the Apache Canyon Formation interfinger with and overlie these alluvial fan facies. The overlying Shellenberger Canyon Formation is composed mostly of terrigenous rocks derived from westerly terranes. This formation contains thick sequences of fluvio-deltaic facies as well as a thin interval of estuarine deposits which mark a northwestern extension of the marine transgression in the Bisbee -Chihuahua Embayment. The youngest formation (Upper Cretaceous?) in the Bisbee Group, the Turney Ranch Formation, consists of interbedded sandstones and marls which were deposited by fluvial and marine(?) processes. alluvial fans Apache Canyon Formation Aptian Arizona Basin and Range Province Bisbee Group Bisbee-Chihuahua Embayment Carboniferous Cochise County Arizona Comanchean Cretaceous deltaic environment depositional environment environment estuarine environment fluvial environment Glance Conglomerate lithofacies Lower Cretaceous Mesozoic Naco Group North America Paleozoic Pennsylvanian Permian Pima County Arizona Santonian sedimentary rocks sedimentation Senonian Shellenberger Canyon Formation southeastern Arizona stratigraphy Turney Ranch Formation unconformities United States Upper Cretaceous Whetstone Mountains Willow Canyon Formation Geology, Stratigraphic. Sediments (Geology) Geology -- Arizona -- Pima County. Geology -- Arizona -- Cochise County.

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