Investigating volcano tectonic interactions in the Natron Rift of the East African Rift System

Jones, Joshua Robert

10 June 2021

Continental rifting, like other plate tectonic processes, plays a large role in shaping the Earth's crust. Active rift zones evolve from repeated tectonic and magmatic events including volcanic activity. Through investigations of currently and previously active rifts, scientists have discovered considerable interactions between these tectonic and magmatic processes during a rift's evolution; however questions remain about these interactions especially in youthful stages of rifts. We investigate an early phase magma-rich section of the East African Rift System (EARS), named the Eastern Branch to assess volcano-tectonic interactions. The Eastern Branch of the EARS consists of volcanically rich rifts that are actively spreading the Nubian Plate, Somalian plates, and Victoria block at different evolutionary stages making it an ideal study area for volcano-tectonic interactions. Our initial investigation of active volcano-tectonic interactions centered on a rifting event that occurred between 2007-2008 in the Natron Rift, a rift segment in the southern Eastern Branch located in Northern Tanzania. This rifting event contained multiple occurrences of tectonic, magmatic, and volcanic activity in close proximity. We examine the stress transferred from these events to the Natron Fault, which is the major border fault in the area, with analytical modeling using the USGS program Coulomb 3.4. We processed Global Positioning System (GPS) data that recorded slip on the major border fault in the region in early January 2008 and test which events could generate large enough stress changes to trigger the observed slip using a previously defined threshold of 0.1 MPa. These initial models were created using simplified model parameters, such as an elastic homogeneous half-space, and find that 1) magmatically induced stress perturbations have the potential to trigger fault slip on rift border faults, 2) magmatic events have the potential to trigger strike‐slip motions on a rift border fault, and 3) the proximity of magmatic activity may affect occurrences of slip on adjacent border faults. We then further investigate volcano-tectonic interactions in the Natron Rift by testing using numerical modeling with the CIG finite element code PyLith. We systematically test how adding topography, heterogeneous materials, and various reservoir volumes to a deflating 3 km deep magma reservoir system at the active volcano Ol Doinyo Lengai can affect stress transfer to the adjacent Natron Fault. We compare eight models with variations in topography, material properties, and reservoir volumes to calculate the percent differences between the models; to test their effects on the stress change results. We find that topography plays the largest role with the effect increasing with reservoir size. Finally, we seek to improve the capability of investigating volcano-tectonic interactions in the Natron Rift at faster time- scales by improving Global Navigation Satellite System (GNSS) positioning data (latitude, longitude, and height) collection and distribution capabilities. In the final part of this work, we describe a new Python-based data broker application, GNSS2CHORDS, that can stream real-time centimeter precision displacement data distributed by UNAVCO real-time GNSS data services to an online EarthCube cybertool called CHORDS. GNSS2CHORDS is applied to the TZVOLCANO GNSS network that monitors Ol Doinyo Lengai in the Natron Rift and its interactions with the adjacent rift border fault, the Natron Fault. This new tool provides a mechanism for assessing volcano-tectonic interactions in real-time. In summary, this work provides a new avenue for understanding volcano-tectonic interactions at unprecedented, 1-second time-scales, demonstrates slip can be triggered by small stress changes from magmatic events during early phase rifting, and provides insights into the key role of volcanic topography during volcano-tectonic interactions. / Doctor of Philosophy / Investigating interactions between active volcanoes and tectonics (fault zones) is important for understanding how continental rifts grow and evolve over time. Modern researchers use geodetic data, geologic models, and computer simulations of rift processes; like volcanic eruptions and fault movement; to understand how stress in transferred and material deforms due to rift activity. We are especially interested in understanding the stress interactions when volcanic eruptions and earthquakes happen together over a short time period. Our projects apply these tools to examine a segment of the largest active continental rift zone, the Natron Rift in the East African Rift System (EARS), to understand more about the details of these volcano-tectonic interactions when continents break apart (rifting). We first present results that stress transferred to the Natron Fault associated with magmatic activity from the volcano Ol Doinyo Lengai may trigger a major fault to move. Next, we continue our investigations into volcano-tectonic interactions by seeing how volcanic properties could affect stress transferred in the Natron Rift region. We choose to initially test stress variations associated with different 1) topography surfaces, 2) material properties, and 3) reservoir volumes associated with the volcano Ol Doinyo Lengai using a more advanced computer modeling approach. This deeper investigation provides information about the individual roles these parameters play in a younger rift region. We present results that topography has the most influence on the stress transferred to the Natron Fault in our models, and that the other parameters did not play a large role in influencing the stress transferred. Finally we work to increase the ability for researchers to perform geodetic studies in the Natron Rift by providing a new method to share surface displacement data at an unprecedented 1 position a second rate (near real-time). This new method is a data broker application called GNSS2CHORDS that can stream cm precision displacement data to an online cybertool called CHORDS. With our models and data provided through open source methods this work contributes significantly to our understanding of volcano-tectonic interactions.

Geodesy

volcanoes

rifting

Magnetotelluric studies of the crust and upper mantle in a zone of active continental breakup, Afar, Ethiopia

Johnson, Nicholas Edward

January 2013

The Afar region of Ethiopia is slowly being torn apart by the Red Sea, Gulf of Aden and Main Ethiopian rifts which all meet at this remote, barren corner of Africa. Prior to rifting, volcanism probably started here some 30 million years ago, marked by the arrival of the Afar mantle plume and subsequent eruption of kilometres thick flood basalts. To the north and east the Red Sea and Gulf of Aden rifts have already progressed to become sea-floor spreading centres where new oceanic crust is produced. Active spreading on the Red Sea rift takes a landward step west into Eritrean Afar at approximately 15oN, after which divergence between the Nubian and Arabian tectonic plates is localised into 60 km long, 20 km wide magmatic segments that undergo periodic rifting cycles. This part of Afar is a unique natural laboratory where the process of transition from continental rifting to sea floor spreading can be studied. In September 2005 a dramatic rifting episode began on one such segment of the Red Sea rift in Afar (the Dabbahu magmatic segment), whereby a 60 km long dyke containing an estimated 2.5 km3 magma was intruded in just two weeks, allowing opening of up to 8 m. Since then a further 13 smaller dykes have been intruded, some with fissural eruptions of basaltic lava. Subsidence observed via geodetic observations can only account for a small fraction of the magma supply required to in ate the dykes, suggesting a deep crustal or upper mantle source must exist. The magnetotelluric (MT) method is a passive geophysical technique, used to probe the Earth to reveal subsurface conductivity. The presence of fluids can dramatically increase conductivity by orders of magnitude making the MT method ideally suited to detecting them. MT data collected from 22 sites on profiles near to and crossing the active rift are analysed and interpreted in conjunction with seismic and petrological constraints. They reveal for the first time, the existence of both a mid to lower-crustal magma chamber directly below the rift, and an o -axis zone of partial melt well within the mantle. The volume of melt contained within the crust and upper mantle below the Dabbahu segment is estimated to be at least 350 km3; enough to supply the rift at current spreading rates for almost 30 thousand years, assuming that both melt containing regions supply the rift. Vast amounts of highly conductive material, suggesting the existence of pure melt in places, are also required in the shallow crust close to Dabbahu volcano which lies at the northern end of the segment. Further data collected on the currently inactive Hararo segment which is the next one to the south of Dabbahu, show a smaller zone of partial melt that appears to be pooling at the Moho, inferred seismically to be at about 22 km, but little or no melt is required within the mid-crust. The minimum amount of melt estimated to be contained here is just 21 km3; an order of magnitude less than on the Dabbahu segment, but similar to estimates for melt within the crust found below the rift axis in the continental Main Ethiopian rift. This, along with other morphological evidence, suggests that this rift segment is less mature than the Dabbahu segment to the north, rather than it simply being at a different stage of a rifting cycle. A wide spread layer of highly conductive sediments up to 2 km thick has been imaged at most locations. This was unexpected on the Dabbahu segment where the surface of the Earth is dominated by heavily faulted basalts erupted from fissures, which are seen as a resistive uppermost layer several hundred metres thick. The high conductivity of the sediments is attributed to high heat flow and the presence of brines.

551.2

CYCLE-UP OF MULTIPLE RIFTING EVENT MODELS: HOW LONG DOES IT TAKE TO REACH A STEADY STATE STRESS?

Ravi, Lokranjith K

01 January 2005

Many geological numerical models are initiated with a background stress state of zero. Often these numerical results are compared directly to geodetic data. Recent work (Kenner and Simons, 2004) has shown that modeled deformation rates can change as the model is cycled-up following repeated earthquakes or rifting events. In this study, we investigate model cycle-up in the context of time-dependent deformation following rifting during the 1975-1984 Krafla eruption in Iceland. We consider the number of rifting cycles required for complete cycle-up, variations in cycle-up time at different locations in the model, background stress magnitudes in fully cycled-up models, and errors incurred when the models are not properly cycled-up. The modeling is done using the commercial software ABAQUS. In ABAQUS a user-defined subroutine is used to apply repeated rifting events within the finite element model. We have generated various 3D models with different fault/rift geometries. The models include (1) a straight rift oriented perpendicular to the far-field velocity boundary conditions, (2) a rift oriented at an angle to the far-field velocities, (3) a model containing two intersecting rifts, one perpendicular to the far-field velocities and the other rift intersecting the first at an angle, and (4) overlapping rift segments in which the overlapped region is bounded by strike-slip faults.

Petrologische und geochemische Untersuchungen an Magmatiten der Gardar-Provinz, Südgrönland

Halama, Ralf,

January 2003

Tübingen, Univ., Diss., 2003.

Miocene intra-arc rifting in SW Japan: Tectonostratigraphy of the Hokutan Group and the paleostress analyses of dike orientations / 西南日本の中新世弧内リフティング：北但層群の地質構造発達史と岩脈の応力解析

Haji, Toshiki

23 March 2020

京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第22265号 / 理博第4579号 / 新制||理||1657(附属図書館) / 京都大学大学院理学研究科地球惑星科学専攻 / (主査)教授 山路 敦, 教授 田上 高広, 教授 生形 貴男 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM

backarc spreading

intra-arc rifting

tectonostratigraphy

paleostress analysis

400

From continental rifting to conjugate margins : insights from analogue and numerical modelling / Du rifting continental aux marges conjuguées : aperçus de la modélisation analogique et numérique

Beniest, Anouk

08 December 2017

Les marges conjuguées de l'Atlantique Sud sont le produit du rifting et de la rupture du continent Pangée. Ce continent présente une hétérogénéité crustale et lithosphérique importante, dont la prise en compte est un objectif de la thèse. Afin de comprendre la rupture continentale à l'échelle lithosphérique de systèmes de rhéologies préexistantes très différentes, nous avons effectué des modélisations, analogique et numérique. Les modèles analogiques s'attachent à montrer l'effet des forces externes sur un tel système hétérogène tandis que les modèles numériques, thermomécaniques, se concentrent sur l'impact des anomalies de fusion du manteau sur le rifting avec une telle configuration.Avec la modélisation analogique, l'effet des forces aux limites sur un système composé de deux segments de rhéologies différentes a été testé à l’échelle de la lithosphère pour comprendre l'influence de l'hétérogénéité rhéologique dans un système en extension. Les résultats montrent que dans un système combiné, toute l'extension se produit dans le segment faible et que le contact entre les deux segments ne joue pratiquement aucun rôle dans l'initiation des failles. Lorsque le segment le plus faible contient une couche résistante dans le manteau supérieur, le rift évolue en deux phases. La première phase montre un système de failles larges où la déformation est distribuée. Une fois que la partie résistante du manteau supérieur est suffisamment affaiblie, l'extension se localise le long d'une zone de faille étroite. Si l'extension continuait, la rupture se produirait à cet emplacement, dans une partie plutôt homogène alors que le système est latéralement hétérogène. Le résultat de ce système extensif serait des marges asymétriques avec une croûte faible/hyper-étirée sur deux marges.Les résultats numériques montrent que, dans le cas de la rupture continentale induite par un panache, le mode de rupture «central», où la rupture se localise au-dessus du point de l'impact du panache, est une forme de rupture continentale parmi d'autres. Ainsi, lorsque l'anomalie de fusion du manteau est localisée de manière décalée par rapport au contact entre les segments rhéologiques, un mode de rupture "décalé" peut se développer. Dans ce cas, le matériel du panache atteint la base de la lithosphère et s’écoule latéralement jusqu’au contact entre les deux segments rhéologiques où le rifting se localise in fine. La partie du matériel qui n’arrive pas au centre de la zone de rupture, se situe au niveau de la croûte inférieure ou bien plus profond, ressemblant aux corps de densité/vitesse élevées imagés le long des marges de l'Atlantique Sud. De plus, le mode «décalé» reproduit l'asymétrie des marges conjuguées... / The South Atlantic conjugate margins are the product of continental rifting and break-up of Pangea, which was made up of different crustal features prior to rifting. This study investigates continental rift initiation and break-up of alternative lithospheric setups, consisting of large segments with different rheological strength, with the use of analogue and numerical modelling. The analogue models investigate the effect of far-field forces on a system that consist of multiple rheological segments, whereas the numerical models include thermal processes and focus on the impact of initial plume emplacement on such a setup.Lithosphere-scale analogue models consisting of two different rheological compartments have been subjected to extensional forces, to understand effect of far-field forces on large rheological heterogeneities in a system within an extensional tectonic regime. The results show that in such a system, the weaker segment accommodates all the extension. At the contact between the two compartments no rift-initiation is observed. In the presence of a strong sub-Moho mantle, the rift evolution consists of two phases. The first phase is a wide or distributed rift event. Once the strong part of the upper mantle has sufficiently weakened, the rift localizes and a narrow rift continues to accommodate the extension. If extension would continue, break-up would happen at the location of the narrow rift, thereby breaking a rather homogenous part within a laterally heterogeneous system. This would result in asymmetric margins with hyperextended, weak crust on both margins.The numerical results show that, in the case of plume-induced continental break-up, the classical ‘central’ mode of break-up, where the break-up centre develops above the plume-impingement point is not the only form of continental break-up. When the mantle anomaly is located off-set from the contact between rheological segments, a ‘shifted’ mode of break-up may develop. In this case, the mantle plume material rises to the base of the lithosphere and migrates laterally to the contact between two rheological segments where rifting initiates. Mantle material that does not reach the spreading centre and remains at lower crustal depths, resemble high density/high velocity bodies at depth found along the South Atlantic margin and providing geometric asymmetry.Further investigation on the exact influence of the initial plume position with respect to the contact between the rheological compartments shows that there is a critical distance for which the system develops either ‘central’ (or ‘plume-induced’) continental break-up or ‘shifted’ (or ‘structural inherited’) continental break-up. For Moho temperatures of 500 – 600 oC, there is a window of ~50 km where the system creates two break-up branches. These results explain complex rift systems with both vertical penetration of plume material into the overlying lithosphere as well as reactivated inherited structures developing break-up systems both aided by the same mantle plume...

Rifting

La rupture continentale

Atlantique Sud

Rhéologie

Modélisation analogique

Modélisation thermomécanique

Marges conjuguées

Lithosphère

Rifting

Continental break-up

South Atlantic

551.1

Influence de l’héritage structural sur le rifting : exemple de la marge Ouest de La Sonde / Influence of pre-existing fabrics in the structures and Evolution of the Rifting : insights from the western margin of Sunda Plate

Sautter, Benjamin

14 March 2017

Les bassins sédimentaires se développent souvent le long des zones internes d'anciennes chaînes orogéniques. Nous considérons dans ce projet la Péninsule Malaise (Marge Ouest de la Sonde) comme un haut crustal séparant deux régions de croûte continentale étirée ; les bassins d'Andaman/Malacca du côté occidental et les bassins thaïlandais/malais à l'est. Plusieurs stades de rifting ont été documentés grâce à une intense exploration géophysique régionale. Cependant, la corrélation entre les bassins riftés en mer et le noyau continental terrestre est mal connue. Dans ce mémoire, nous explorons par la cartographie, de missions de terrain et les données sismiques, comment ces structures réactivent des hétérogénéités mésozoïques crustales préexistantes. Le noyau continental semble être relativement peu déformé après l'orogénèse triasique Indosinienne. L’épais méga-horst crustal est bordé par des zones de cisaillement complexes (zones de failles de Ranong, Klong Marui et du Batholithe du Main Range) initiées au Crétacé Supérieur/Paléogène inférieur lors d’une déformation transpressive d’échelle crustale et plus tard réactivées à la fin du Paléogène. L'extension est localisée sur les bords de cette épine dorsale crustale le long d'une bande où la précédente déformation crétacée supérieure est bien exprimée. À l'ouest, le plateau continental est aminci en trois étapes principales qui correspondent à des blocs basculés d’échelle crustale bordés par de larges failles contre-régionales profondément enracinées (Bassin de Mergui). À l'est, des systèmes de rifts prononcés sont également présents, avec de grands blocs basculés (les bassins western Thai, de Songkhla et de Chumphon) qui pourraient représenter de grands boudins de croûte. Dans le domaine central, l'extension est limitée à de demi-grabens étroits isolés de direction N-S développés sur une croûte continentale épaisse, et contrôlés par failles normales pelliculaires, qui se développent souvent au contact entre les granitoïdes et l’encaissant. Les bords extérieurs des régions affectées par le boudinage crustal délimitent le bassin d'Andaman plus grand et profond à l'ouest et les bassins Malais et de Pattani à l'est. À une échelle régionale, les bassins riftés ressemblent à des structures en-échelon N-S le long de grandes bandes de cisaillement de NW-SE. Le rifting est accommodé par de larges failles normales à faible pendage (LANF : Low Angle Normal Faults) réactivant les morpho-structures de la croûte telles que de larges plis et batholithes mésozoïques. Les bassins profonds d'Andaman, Malais et de Pattani semblent situés sur une croûte à rhéologie plus faible qui pourrait être héritée des blocs continentaux dérivés du Gondwana (Birmanie, Sibumasu, et Indochine). L'ensemble des long bassins étroits au coeur de la région (bassins de Khien SA, de Krabi, et du Malacca) apparaissent avoir souffert de relativement peu d'extension. Ce travail montre que le cœur de l’orogène Crétacé supérieure est faiblement réactivé avec seulement quelques traces d’un étirement précoce par rapport aux bords qui sont sujets à un amincissement crustal en larges blocs basculés. A mesure que la déformation augmente, le rifting migre et se localise vers les zones externes et sa géométrie apparait plus « molle » suggérant un mécanisme influencé par la thermique. La coexistence de ces deux géométries au sein d’un même cycle de rifting fait de la marge Ouest de la sonde un cas d’étude édifiant. / Sedimentary basins often develop above internal zones of former orogenic belts. We hereafter consider the Malay Peninsula (Western Sunda) as a crustal high separating two regions of stretched continental crust; the Andaman/Malacca basins in the western side and the Thai/Malay basins in the east. Several stages of rifting have been documented thanks to extensive geophysical exploration. However, little is known on the correlation between offshore rifted basins and the onshore continental core. In this paper, we explore through mapping and seismic data, how these structures reactivate pre-existing Mesozoic basement heterogeneities. The continental core appears to be relatively undeformed after the Triassic Indosinian orogeny. The thick crustal mega-horst is bounded by complex shear zones (Ranong, Klong Marui and Main Range Batholith Fault Zones) inititiated during the Late Cretaceous/Early Paleogene during a thick-skin transpressional deformation and later reactivated in the Late Paleogene. The extension is localized on the sides of this crustal backbone along a strip where earlier Late Cretaceous deformation is well expressed. To the west, the continental shelf is underlain by three major crustal steps which correspond to wide crustal-scale tilted blocks bounded by deep rooted counter regional normal faults (Mergui Basin). To the east, some pronounced rift systems are also present, with large tilted blocks (Western Thai, Songkhla and Chumphon basins) which may reflect large crustal boudins. In the central domain, the extension is limited to isolated narrow N-S half grabens developed on a thick continental crust, controlled by shallow rooted normal faults, which develop often at the contact between granitoids and the host-rocks. The outer limits of the areas affected by the crustal boudinage mark the boundary toward the large and deeper Andaman basin in the west and the Malay and Pattani basins in the east. At a regional scale, the rifted basins resemble N-S en-echelon structures along large NW-SE shear bands. The rifting is accommodated by large low angle normal faults (LANF) running along crustal morphostructures such as broad folds and Mesozoic batholiths. The deep Andaman, Malay and Pattani basins seem to sit on weaker crust inherited from Gondwana-derived continental blocks (Burma, Sibumasu, and Indochina). The set of narrow elongated basins in the core of the Region (Khien Sa, Krabi, and Malacca basins) suffered from a relatively lesser extension. This work shows that the core of the late Cretaceous Orogeny is weakly reactivated during the subsequent rifting with only few evidences of stretching whereas its sides are thinned with large tilted blocks. The rifting migrates and localizes on the external regions and its geometry appears more ductile suggesting the influence of a thermal activity in the process. The coexistence of both geometries in a single rifting cycle makes the western margin of Sundaland an enlightening example.

Rifting

Réactivation d'orogène

Bassins Crétacé/Tertiaire

Exhumation de Granite

Péninsule Malaise

Plaque de la Sonde

Rifting

Reactivation of Orogen

Cretaceous/Tertiary basins

Granite exhumation

Malay Peninsula

Sundaland

550

Etude des conditions de formations du gisement de talc-chlorite de Trimouns (Ariège, France) / Conditions of formation of the Trimouns talc-chlorite deposit (Ariège, France)

Boutin, Alexandre

27 September 2016

Le gisement de talc-chlorite de Trimouns est situé dans le massif nord-pyrénéen du Saint Barthélémy (Ariège, France). Il est l'objet d'une attention particulière pour ses ressources minérales exceptionnelles (tant par la qualité que l'abondance), et pour sa position stratégique dans l'histoire géologique des Pyrénées. Le but de cette étude est de caractériser les conditions de formation du gisement et de les intégrer dans le contexte géologique régional. Pour aborder cette problématique nous avons choisi trois grands axes d'étude : 1) au moyen de l'analyse cartographique et structurale, nous procédons à une description de la géométrie du gisement, et nous proposons une histoire des relations entre minéralisation et déformation ; 2) à l'aide d'analyses thermométriques via plusieurs méthodes, nous cherchons à définir quelle est l'histoire thermique enregistrée dans les différentes unités du gisement ; 3) avec des datations in situ sur un large panel de minéraux, nous positionnons des repères temporels sur plusieurs objets géologiques afin de dater le ou les épisodes minéralisateurs sur Trimouns. Les résultats obtenus expriment le caractère polyphasé du gisement, et ce pour les trois axes d'études suivis, déformation, thermicité et âge de la minéralisation. Les travaux sur les structures montrent que la minéralisation principale scelle une déformation probablement varisque, minéralisation qui se forme elle-même en contexte dynamique et qui est à son tour déformée. L'étude thermique met en évidence que la ou les minéralisations sont associées à un ou plusieurs événements froids, et qu'une empreinte thermique chaude est préservée dans les roches du toit et du mur du gisement. Les résultats géochronologiques montrent que la formation du talc et des chlorites à Trimouns est polyphasée et associée à une succession d'événements métasomatiques. L'Albien est l'évènement hydrothermal majeur mais des épisodes plus anciens sont enregistrés au Jurassique à Trimouns, voire au Permien dans d'autres gisements du massif et de l'ouest de la chaîne des Pyrénées. La synthèse de nos travaux nous permet de proposer un modèle de la formation du gisement de talc-chlorite de Trimouns. Ce modèle s'inscrit dans un contexte géodynamique extensif post-varisque que l'on peut mettre en relation avec les phénomènes extensifs pré-orogéniques pyrénéens du Crétacé (120-85 Ma). Ce contexte pré-orogénique est associé à l'exhumation du manteau, source probable du magnésium nécessaire à la formation du gisement. Nos travaux montrent également que le massif du Saint Barthélémy, et possiblement d'autres massifs nord pyrénéens semblables, ne sont pas des massifs "simplement" varisques mais qu'ils ont pu être profondément affectés par les évènements du cycle alpin. / The Trimouns talc-chlorite deposit is located in the north Pyrenean Saint Barthelemy massif (Ariège, France). This deposit is remarkable in its minerals' quality and quantity as well as for its strategic position in the Pyrenees geological history. This study aims at understanding the formation conditions of the talc-chlorite deposit and at integrating them in the alpine pre-orogenic context. To this, we focus on three main themes : 1) Using geological and structural mapping studies, we describe the rocks and their organization as to estimate how much variscan and alpine orogenies affected them. 2) With thermometric analyses using different methods, we seek to define what is the thermal history recorded in the different units of the deposit. 3) Using in-situ dating on a wide range of minerals, we locate temporal references on various geological objects to document hydrothermal events. Achieved results demonstrate the polyphase caracteristics of the deposit, in the three focal areas used : deformation, thermal approach, and geochronology. Structural analysis shows that the mineralisation seals an other deformation, probably of the variscan period. This mineralisation is also formed in a dynamic context and then deformed as well. The thermal study highlights that mineralizations are associated with one or more cold events, and a hot thermal foot-print is preserved in the footwall and the hanging wall of the deposit. Dating results show that the formation talc and chlorite in Trimouns is multiphase, associated with succession of metasomatic events. The Albian event is the major hydrothermal event but older episodes are recorded in Jurassic at Trimouns and in Permian in other fields on the west-ern Pyrenees. The synthesis of our works allows us to propose a model of the formation of the Trimouns talc-chlorite deposit. This model is part of a post-Variscan extensive geodynamic context that can be related to the Pyrenean extensive pre-orogenic phenomena during Cretaceous period (120-85 Ma). This pre-orogenic context is associated with mantle exhumation, likely source of magnesium necessary for the formation of talc. Our studies also show that the Saint Barthelemy massif and possibly other similar north Pyrenean massif are not "simply" Variscan but have been deeply affected by the events of the Alpine cycle.

Trimouns

Talc

Chlorite

Pyrénées

Métasomatisme

Cycle alpin

Cycle varisque

Processus géologiques

Rifting

Extension crustale

Trimouns

Talc

Chlorite

Pyrenees

Metasomatism

Alpine cycle

Variscan cycle

Geological processes

Rifting

Crustal thinning

La bordure nord de la plaque ibérique à l'Albo-Cénomanien : architecture d'une marge passive de type ductile (Chaînons Béarnais, Pyrénées Occidentales) / The Northern edge of the Iberian plate during Albian-Cenomanian times : architecture of a ductile-type passive margin (Chaînons Béarnais, Western Pyrenees)

Corre, Benjamin

01 December 2017

Le manteau lithosphérique subcontinental est exhumé au pied des marges passives distales non-volcaniques en réponse à l’amincissement extrême de la croûte continentale. Ce processus d’amincissement peut être étudié à pied sec sur les témoins de la paléo-marge passive nord Ibérique affleurant aujourd’hui au nord de la chaîne des Pyrénées dans les Chaînons Béarnais (Zone Nord-Pyrénéenne : ZNP). La ZNP résulte de l’inversion de bassins ouverts entre les plaques Ibérique et Europe pendant l’Albo-Cénomanien. Dans les Chaînons Béarnais, la couverture mésozoïque pré-rift est intimement associée aux roches du manteau subcontinental et à de fines lentilles tectoniques de croûte continentale. L’hyper amincissement crustal s’est déroulé dans des conditions thermiques relativement chaudes, comme le montrent les déformations ductiles syn-métamorphiques crétacées affectant la croûte continentale et la couverture mésozoïque allochtone, localement en contact tectonique sur le manteau exhumé. Dans cette thèse, nous présentons des données structurales et géochimiques apportant de nouvelles contraintes pour la connaissance du processus d’amincissement extrême de la croûte continentale et pour la reconstruction de l’évolution de la paléo-marge nord-Ibérique. La couverture pré-rift a été désolidarisée de son socle paléozoïque au niveau des évaporites du Keuper et mise en contact direct avec le manteau pendant son exhumation dans le fond des bassins. Le détachement croûte/manteau est une discontinuité majeure caractérisée par des bandes de cisaillements anastomosées définissant une fabrique lenticulaire (« phacoidal fabric ») d’épaisseur pluri-métrique au sommet du manteau serpentinisé. La croûte continentale se réduit à de minces écailles elles-mêmes anastomosées, séparée par des bandes de cisaillement dans le faciès schistes verts et évoluant vers des cataclasites plus froides. Les analyses par spectrométrie Raman sur la matière carbonée (RSCM) montrent que l’ensemble de la couverture mésozoïque a été soumis à des températures maximales comprises entre 200°C et 480°C. Elle est sujette à d’intenses circulations de fluides. Les interactions fluides/roches ont eu lieu lors de tous les stades de l’extension, depuis les contextes profonds durant la déformation ductile, jusqu’au domaine superficiel durant la déformation cassante. Le détachement manteau/Mésozoïque est marqué par une couche de roches métasomatiques, riches en talc, chlorite et pyrite, mises en place dans les conditions du faciès schistes verts, impliquant en partie des fluides issus de la serpentinisation du manteau. De plus, la géochimie isotopique (O, C, Sr) et les inclusions fluides présentes dans des veines de carbonates des sédiments mésozoïques, témoignent d’une circulation de saumures chaudes (~200°C), à travers toute la couverture sédimentaire pendant l’exhumation du manteau. Ces saumures sont issues de la dissolution des évaporites du Keuper, très rarement conservées dans les Chaînons Béarnais. Nous développons un modèle conceptuel basé sur la géologie des Chaînons Béarnais dans lequel la croûte continentale moyenne est déformée ductilement. Le fonctionnement de détachements contre-régionaux (à pendage vers le continent) est associé à l’individualisation de fines lentilles tectoniques de croûte continentale moyenne qui sont extraites et exhumées avec le manteau dans le fond des bassins albo-cénomaniens, laissant en arrière la croûte continentale supérieure et inférieure. Ces lentilles crustales collées au manteau forment alors une large zone de croûte extrêmement amincie. Des fenêtres ouvertes au sein de cette mince pellicule crustale permettent au manteau de venir en contact direct avec les sédiments pré-rifts (Saraillé, Turon de la Técouère). Des ouvertures au sein de la couverture pré-rift permettent au manteau de venir directement à l’affleurement (Urdach-Les Pernes). / Sub-continental lithospheric mantle rocks are exhumed at the foot of magma-poor distal passive margins as a response to extreme stretching of the continental crust. Remnants of the Northern Iberian paleo-passive margin are now exposed in the Northern Pyrenees in the Chaînons Béarnais (North Pyrenean Zone: NPZ) and represent field analogues to study the processes of continental crust thinning and subcontinental mantle exhumation. The NPZ results from the inversion of basins opened between the Iberia and Europa plates during Albo-Cenomanian times. In the Chaînons Béarnais ranges the pre-rift Mesozoic sedimentary cover is associated with peridotite bodies in tectonic contact with small size Paleozoic basement lenses. Continental extension developed under hot thermal conditions, as demonstrated by the syn-metamorphic Cretaceous ductile deformation affecting both the crustal basement and the allochtonous Mesozoic cover locally in direct contact with exhumed mantle rocks. In this study, we present structural and geochemical data providing new constraints to the knowledge of extreme crustal thinning processes and to reconstruct the evolution of the northern Iberia paleo-margin. The pre-rift cover was detached from its Paleozoic bedrock at the Keuper evaporites level and was welded to mantle rocks during their exhumation in the bottom of the basins. The crust/mantle detachment fault is a major shear zone characterized by anastomosed shear bands defining a plurimetric phacoidal fabric at the top of the serpentinized mantle. Raman Spectroscopy on Carbonaceous Materials (RSCM), performed on the Mesozoic cover reveals that the entire sedimentary pile underwent temperatures ranging between 200°C and 480°C. This sedimentary pile displays numerous evidence of infiltration by geological fluids. The fluid/rock interactions went on during the entire extensional events, since early deep phases characterized by ductile deformation, to late shallower stages characterized by brittle deformation. The detachment is marked by a layer of metasomatic rocks, locally up to 20 meters thick, made of talc-chlorite-pyrite-rich rocks that developed under greenschist facies conditions, including fluids derived from mantle rocks serpentinisation. Moreover, isotopes geochemistry (O, C, Sr) and microthermometry/Raman spectrometry of fluid inclusions in a network of calcitic veins (with quartz locally) in the overlying sediments reveal moderate temperatures (~220°C) brines circulation through the whole sedimentary cover during mantle exhumation. These brines likely derived from the dissolution of the local Triassic evaporites, rarely preserved in the Chaînons Béarnais. We developed a conceptual model based on geological evidence from the Chaînons Béarnais. Implying ductile deformation of the middle crust. Counter-regional detachments (dipping toward the continent) are associated to the individualization of mid-crustal thin tectonic lenses which remain welded on the mantle rocks and are exhumed at the floor of the Albian-Cenomanian basins, leaving behind the upper and the lower crust. These crustal lenses welded on mantle rocks then form a large zone of extremely thinned continental crust. Breaking points in this thin crustal sheet allow mantle rocks to come in direct contact with the pre-rift sediments (Saraillé, Turon de la Técouère). Breaking points in the pre-rift cover allow mantle rocks to be completely exhumed to the seafloor (Urdach-Les Pernes).

Déformation ductile

Rifting albo-Cénomanien

Marge passive

Exhumation du manteau

Chaînons Béarnais

Ductile deformation

Albian-Cenomanian rifting

Passive margin

Mantle exhumation

Chaînons Béarnais

Formation et exhumation des granulites permiennes : établir les conditions pré-rift et déterminer l'histoire d'exhumation syn-rift / Formation and exhumation of Permian granulites : establishing pre-rift conditions and syn-rift exhumation history

Petri, Benoît

02 December 2014

Cette étude a visé à contraindre les processus tectoniques, magmatiques et métamorphiques actifs dans la croûte moyenne, du Permien à l’exhumation des roches pendant les riftings mésozoïques, en se focalisant sur un gabbro permien dans les nappes austroalpines (Italie du nord, sud-est de la Suisse). L’évolution du gabbro de Sondalo, mis en place dans l’unité de Campo, est examinée en combinant géologie structurale, pétrologie magmatique et métamorphique, et géochronologie. Les résultats de cette étude (1) apportent des contraintes sur les relations thermiques et mécaniques entre le pluton et l’encaissant pendant sa mise en place dans la croûte moyenne, (2) décrivent les mécanismes d’ascension de magmas mafiques au travers de la croûte continentale et (3) documentent l’exhumation et le refroidissement de l’unité de Campo et de l’unité sus-jacente de Grosina pendant la formation de la marge riftée adriatique. / This study aims to unravel tectonic, magmatic and metamorphic processes active at midcrustal levels from the Permian to the exhumation of the rocks during the Mesozoic riftings by focusing on a Permian gabbro in the Austroalpine nappes (N–Italy, SE–Switzerland). The evolution of the Sondalo gabbro, emplaced in the Campo unit, is examined by combining structural geology, magmatic and metamorphic petrology, and geochronology. The results of this study bring constrains on (1) the thermal and mechanical relationship between the pluton and the host rock during its emplacement in the middle crust, (2) the mechanisms of mafic magmas ascent through the continental crust and (3) the exhumation and cooling history of the Campo unit and the overlying Grosina unit during the formation of the Adriatic rifted margin.

Evolution post-orogénique

Rifting

Alpes

Campo

Grosina

Nappes austroalpine

Varisque

Permien

Post-orogenic evolution

Rifting

Alps

Campo

Grosina

Austroalpine nappes

Variscan

Permian

551.1