Origine de la minéralisation des eaux dans un aquifère multicouche profond : exemple de la "zone minéralisée de l'Entre-Deux-Mers" (Bassin Aquitain, France) / Origin of groundwaters’ mineralization in a deep multi-layered aquifer : example of the “mineralized Entre-Deux-Mers area” (Aquitaine Basin, France)

Malcuit, Eline

02 April 2012

La caractérisation géochimique et isotopique des eaux souterraines de la « zone minéralisée de l’Entre-Deux-Mers » indique une origine commune de la minéralisation, directement liée à la minéralogie des formations captées par les forages.La géochimie montre que les interactions eau-roche sont majoritairement influencées par la présence d’évaporites, mais que d’autres interactions mettant en jeu des carbonates, des silicates et des argiles existent. Un modèle géochimique d’acquisition de la minéralisation reconstitue parfaitement la chimie des eaux souterraines à l’échelle de la zone d’étude. Ce modèle, construit en se basant sur la géochimie des eaux et sur la minéralogie des formations tertiaires du nord du Bassin aquitain, met à l’équilibre des eaux avec des formations carbonatées et évaporitiques. Afin de mieux comprendre la distribution latérale et verticale des formations tertiaires et leur minéralogie, une approche paléogéographique et sédimentologique a permis de localiser les différents horizons riches en sulfates et/ou en fluorures, mais aussi de comprendre leur origine de dépôt. En se basant sur l’hydrogéologie, la paléogéographie, la minéralogie et la géochimie, des hypothèses de répartition de la minéralisation à l’échelle du forage ont pu être testées. Les résultats de la modélisation couplée hydrodynamique–transport reconstituent la chimie des eaux prélevées par les forages de la « zone minéralisée de l’Entre-Deux-Mers ». Au vu de ces résultats, un modèle avec obturation des horizons riches en sulfates et en fluorures a été testé et les résultats obtenus ouvrent des perspectives pour des futures recherches. Ce travail a donc permis de comprendre l’origine de la minéralisation des eaux de « la zone minéralisée de l’Entre-Deux-Mers », mais aussi de proposer des améliorations et des perspectives pour une meilleure gestion d’une des principales ressources en eau potable de la Gironde. / Geochemical and isotopic characterizations of groundwaters in the "mineralized Entre-Deux-Mers area" indicate a common origin of the mineralization, directly linked to the mineralogy of the formations abstracted by drilling.Geochemistry shows that water-rock interactions are mainly influenced by the presence of evaporites, and that but that other interactions involving carbonates, silicates and clays exist. A geochemical model based on the water geochemistry and mineralogy of the Tertiary formations of northern Aquitaine Basin fix waters in equilibrium with evaporitic and carbonated formations. This model reconstitutes perfectly the groundwaters’ chemistry across the study area and explains the mineralization acquisition. Improving the understanding of the lateral and vertical distribution of tertiary formations and their mineralogy requires a sedimentological and paleogeographical approach. This approach allowed to locate the different layers rich in sulphates and/or fluoride and to understand also their origin.Based on hydrogeology, paleogeography, mineralogy and geochemistry, the distribution of the mineralization has been tested at the borehole scale. The results of this coupled hydrodynamic-transport modeling reconstitute the chemistry of the groundwaters in the "mineralized Entre-Deux-Mers area." A model, that considers the sealing of sulphates- and fluorides-rich layers has been tested and its results highlights future research perspectives. This work has allowed understanding the origin of the mineralization of the waters "of the mineralized Entre-Deux-Mers area" and also suggests improvements and prospects for sustainable management of a major drinking water resource in Gironde.

Bassin aquitain

Entre-Deux-Mers

Eocène

Aquifère multicouche

Eaux souterraines

Hydrogéologie

Analyses géochimiques

Interaction eau-roche

Datation

Paléogéographie

Minéralogie

Évaporites

Fluorures

Dilution

Mélange

Aquitaine Basin

Entre-Deux-Mers

Eocene

Multi-layered aquifer

Groundwaters

Hydrogeology

Geochemical and isotopic analyzes

Water-rock interaction

Dating tools

Paleogeography

Mineralogy

Evaporates

Coupled hydrodynamic-and transport model

Dilution/mixture (mixing)

Fluoride

Faciès, architecture et dynamique d’un système margino-littoral tidal : exemple de la Formation du Dur At Talah (Eocène supérieur, Bassin de Syrte, Libye) / Facies, architecture and dynamics of a tidal nearshore system : example of the Dur At Talah Formation (Upper Eocene, Sirt Basin, Libya)

Pelletier, Jonathan

30 October 2012

Ce manuscrit de thèse propose la première étude sédimentologique exhaustive de l’escarpement du Dur At Talah (150 km de long sur 120 m de hauteur). Ce dernier affleure dans la dépression d’Abu Tumayam, dans la partie méridionale du Bassin de Syrte (Libye). La Formation du Dur At Talah offre une séquence sédimentaire régressive (au 2nd ordre), allant de faciès marins peu profonds à des faciès fluviatiles, datée de l’Eocène supérieur. Les exceptionnelles conditions d'affleurement ont permis une analyse sédimentologique approfondie (lithofaciès, ichnofaciès, géométries et découpage séquentiel) conduisant à une caractérisation multiscalaire d'un système margino-littoral dominé par la dynamique tidale. Parmi les résultats saillants de cette étude figure l'identification de deux processus sédimentaires : la progradation signée par des structures clinoformes et l’accrétion latérale caractérisée par des stratifications hétérolithiques inclinées (IHS). Dès lors, plusieurs corps sédimentaires se distinguent sans ambiguïté tel que les barres d’embouchure hétérolithiques et les barres de méandres de chenaux tidaux. L'auscultation de ces grands corps sédimentaires permet alors d'en définir les critères de reconnaissance et le contexte séquentiel de mise en place, mais aussi d'en contraindre le potentiel réservoir. / This manuscript provides the first exhaustive sedimentological study of the Dur At Talah escarpment (≈120 m high and ≈150 km length). This latter is exposed in the Abu Tumayam Trough, in the southern Sirt Basin (Libya). The Dur At Talah Formation forms a 2nd order regressive sequence, from shallow marine to fluviatile deposits, dated as upper Eocene. This exceptional outcrop allows an extensive and detailed sedimentological analysis (lithofaciès, ichnofaciès, geometries and sequence stratigraphy) leading to a multi-scale characterization of nearshore to paralic environments dominated by tidal dynamic. Among outstanding results, two sedimentary processes have been recognized and characterized: the progradation is expressed by large-scale clinoform structures and the lateral accretion is characterized by inclined heterolithic stratifications (IHS). Several sedimentary bodies are, thus, unequivocally distinguishable such as heterolithic mouth-bars and tidal channel point-bars. Thorough analysis of these sedimentary bodies allows to define diagnostic criteria to recognize them. They can be replaced in a consistent stratigraphic framework explaining their architecture and their vertical evolution in order to be used as reservoir analog.

Lithofaciès

Ichnologie

Stratigraphie séquentielle

Dynamique et cyclicité tidales

Géométrie des corps sédimentaires

Chenaux tidaux

IHS

Barres d’embouchure

Clinoformes

Bassin de Syrte

Eocène supérieur

Lithofacies

Ichnology

Sequence stratigraphy

Tidal dynamic and cyclicittes

Sedimentary body architecture

Tidal channels

IHS

Mouth-bars

Clinoforms

Sirt Basin

Upper Eocene

550

The Provenance of Eocene Tuff Beds in the Fossil Butte Member of the Green River Formation of Wyoming: Relation to the Absaroka and Challis Volcanic Fields

Chandler, Matthew R.

25 July 2006

The Green River Formation was deposited between 53.5 and 48.5 Ma. The Angelo, Fossil Butte, and Lower members of the Green River Formation at Fossil Basin, preserve ash fall tuffs deposited in ancient Fossil Lake. 40Ar/39Ar dating of sanidine yielded eruptive ages of 51.29 ± 1.29 Ma and 52.20 ± 3.08 Ma for two of the tuff beds within Fossil Basin. Immobile element and mineral compositions of Fossil Basin tuffs indicate that most tuffs erupted from a subduction zone originally as rhyolites and dacites. X-ray diffraction analyses reveal that the tuffs' glassy matrices have been altered to illite, calcite, clinoptilolite, analcime, albite, and K-feldspar. The variable alteration of the tuff beds confirms previous studies of Fossil Lake's salinity fluctuation through time. One outcrop (FB-10), which was previously interpreted to represent the K-spar tuff, has biotite of different compositions from that in known K-spar tuff samples (FB-09 and FB-11). Tuff horizons from the Greater Green River Basin have feldspar and biotite compositions similar to those from tuffs in Fossil Basin and are interpreted to have the same eruptive sources. Based on age and proximity, the Absaroka and Challis volcanic fields are the likely sources of tephra deposits in Fossil Basin and the Greater Green River Basin. Calc-alkaline tephras in these lacustrine basins have similar magmatic characteristics to the tuff of Ellis Creek (48.4 ± 1.6 Ma) from the Challis volcanic field. However, major and trace element, and mineral compositions of Absaroka and Challis volcanic rocks are not distinctive enough to definitively determine the source of most Fossil Basin and Greater Green River Basin tephras. Two samples, FB-10 from Fossil Basin and WN-79.15 from the Greater Green River Basin, have compositions similar to calc-alkaline magmas, but have some mineral compositions with A-type chemical affinities; consequently we conclude that they were erupted from volcanoes within the Challis volcanic field. Compositions of Challis volcanic rocks may have important implications for the development of a slab window in western North America during the Eocene. Compositional variation of Challis volcanic rocks through time indicates that calc-alkaline rocks with a slight A-type component erupted early in its history, and as the slab window matured the Challis volcanic field dominantly erupted rocks with a more A-type chemical affinity. A slab window may have developed due to the Farallon slab subducting at a shallow angle beneath the North American plate, and gravity may have caused it to break to the north. Through time the slab could have torn to the south and by 50 Ma the slab window would have been opening beneath the Challis volcanic field. This would have erupted calc-alkaline magmas, but upwelling of the asthenosphere into the mantle wedge (beneath the North American plate) would have introduced A-type magmatism into the magmatic system. By 45 Ma, the slab would have matured and opened sufficiently beneath the Challis volcanic field to replace calc-alkaline magmatism with, first "transitional" magmatism, and then A-type magmatism as evident in the youngest Challis tuffs.

Fossil Butte National Monument

Fossil Basin

Green River Formation

Fossil Butte Member

Absaroka volcanic field

Challis volcanic field

Absaroka

Challis

Eocene volcanic rocks

slab window

Greater Green River Basin

Wyoming

Lake Gosiute

Fossil Lake

altered tuff beds

alteration in volcanic rocks

Geology

Geology of the Phil Pico Mountain Quadrangle, Daggett County, Utah, and Sweetwater County, Wyoming

Anderson, Alvin D.

25 April 2008

Geologic mapping in the Phil Pico Mountain quadrangle and analysis of the Carter Oil Company Carson Peak Unit 1 well have provided additional constraints on the erosional and uplift history of this section of the north flank of the Uinta Mountains. Phil Pico Mountain is largely composed of the conglomeratic facies of the early Eocene Wasatch and middle to late Eocene Bridger Formations. These formations are separated by the Henrys Fork fault which has thrust Wasatch Formation next to Bridger Formation. The Wasatch Formation is clearly synorogenic and contains an unroofing succession from the adjacent Uinta Mountains. On Phil Pico Mountain, the Wasatch Formation contains clasts eroded sequentially from the Permian Park City Formation, Permian Pennsylvanian Weber Sandstone, Pennsylvanian Morgan Formation, and the Pennsylvanian Round Valley and Mississippian Madison Limestones. Renewed uplift in the middle and late Eocene led to the erosion of Wasatch Formation and its redeposition as Bridger Formation on the down-thrown footwall of the Henrys Fork fault. Field observations and analysis of the cuttings and lithology log from Carson Peak Unit 1 well suggest that initial uplift along the Henrys Fork Fault occurred in the late early or early middle Eocene with the most active periods of uplift in the middle and late Eocene (Figure 8, Figure 24, Appendix 1). The approximate post-Paleocene throw of the Henrys Fork fault at Phil Pico Mountain is 2070 m (6800 ft). The Carson Peak Unit 1 well also reveals that just north of the Henrys Fork fault at Phil Pico Mountain the Bridger Formation (middle to late Eocene) is 520 m (1710 ft) thick; an additional 460 m (1500 ft) of Bridger Formation lies above the well on Phil Pico Mountain. Beneath the Bridger Formation are 400 m (1180 ft) of Green River Formation (early to middle Eocene), 1520 m (5010 ft) of Wasatch Formation (early Eocene), and 850 m (2800 ft) of the Fort Union Formation (Paleocene). Stratigraphic data from three sections located east to west across the Phil Pico Mountain quadrangle show that the Protero-zoic Red Pine Shale has substantially more sandstone and less shale in the eastern section of the quadrangle. Field observations suggest that the Red Pine Shale undergoes a facies change across the quadrangle. However, due to the lack of continuous stratigraphic exposures, the cause of this change is not known.

Eocene

Red Pine Shale

Uinta Mountains

Bridger Formation

Wasatch Formation

Henrys Fork Fault

Uplift

uplift history

anticline

syncline

Laramide

Green River Formation

Bishop Conglomerate

inverted cobble stratigraphy

unroofing

unroofing sequence

conglomerate

Phil Pico Mountain

Flaming Gorge

Utah

Wyoming

Paleocene

clast

erosional history

north flank

facies change

strike-slip fault

Madison Limestone

Weber Sandstone

Vr

VrTwo

VrOne

geologic mapping

geology

glacial deposits

Smiths Fork

Uinta thrust

cuttings

lithology log

erosion

Carson Peak well

geologic map

cross-section

stratigaphy

stratigraphic column

unit descriptions

tectonic history

Tertiary

depositional

deposition

Proterozoic

Precambrian

Geology