The deglaciation of the northwest sector of the last British-Irish ice sheet : integrating onshore and offshore data relating to chronology and behaviour

Small, David

January 2013

It is now accepted that the last British-Irish Ice Sheet (BIIS) was highly dynamic and drained by numerous fast flowing ice streams. This dynamic nature combined with its maritime location made the BIIS sensitive to the rapid climate change that characterised the Last Glacial Interglacial Transition. Gaining an understanding of the behaviour of the BIIS at this time is important to explore the nature of forcing between ice sheets and climate. This thesis presents new chronological data relating to the deglaciation of the northwest sector of the BIIS (NW-BIIS) from onshore dating of moraines using cosmogenic exposure dating. This improved chronological framework is supported by offshore data in the form of a newly constructed Ice Rafted Detritus (IRD) record from the offshore sediment core MD95-2007. These data suggest that deglaciation commenced sometime after 18 ka and that the NW-BIIS was located close to the present day shoreline by 16 ka. Further provenance analysis of the IRD using U-Pb dating of detrital minerals demonstrates that during the Last Glacial-Interglacial Transition MD95-2007 was being supplied distal IRD from a source(s) to the west. The absence of diagnostic Scottish material suggests that after retreat to the coastline at 16 ka calving margins were not re-established during Greenland Interstadial 1. By combining these results with existing data relating to the deglaciation of the NW-BIIS it is possible to summarise the deglaciation history of the NW-BIIS from the continental shelf to mountainous source regions and compare this to numerical models of BIIS behaviour during this time. With a better understanding of the chronology of NW-BIIS retreat it is possible to relate the timing of initial deglaciation to possible forcing factors and gain a better understanding of the response of a marine based sector of an ice sheet to rapid climate change.

551.31

Understanding an evolving diffuse plate boundary with geodesy and geochronology

Lifton, Zachery Meyer

13 January 2014

Understanding spatial and temporal variations in strain accumulation and release along plate boundaries is a fundamental problem in tectonics. Short-term and long-term slip rates are expected to be equal if the regional stress field remains unchanged over time, yet discrepancies between modern geodetic (decadal time scale) slip rates and long-term geologic (10^3 to 10^6 years) slip rates have been observed on parts of the Pacific-North American plate boundary system. Contemporary geodetic slip rates are observed to be ~2 times greater than late Pleistocene geologic slip rates across the southern Walker Lane. I use a combination of GPS geodesy, detailed field geologic mapping, high-resolution LiDAR geodetic imaging, and terrestrial cosmogenic nuclide geochronology to investigate the observed discrepancy between long- and short-term slip rates. I find that the present day slip rate derived from GPS geodesy across the Walker Lane at ~37.5°N is 10.6 ± 0.5 mm/yr. GPS data suggest that much of the observed discrepancy occurs west of the White Mountains fault zone. New dextral slip rates on the White Mountains fault zone of 1.1 ± 0.1 mm/yr since 755 ka, 1.9 +0.5/-0.4 mm/yr since 75-115 ka, 1.9 +0.5/-0.4 mm/yr since 38.4 ± 9.0 ka, and 1.8 +2.8/-0.7 mm/yr since 6.2 ± 3.8 ka are significantly faster than previous estimates and suggest that slip rates there have remained constant since the middle Pleistocene. On the Lone Mountain fault I calculate slip rates of 0.8 ± 0.1 mm/yr since 14.6 ± 1.0 ka and 0.7 ± 0.1 mm/yr since 8.0 ± 0.5 ka, which suggest that extension in the Silver Peak-Lone Mountain extensional complex has increased dramatically since the late Pleistocene.

Plate boundary

Active tectonics

Fault

Slip rate

Geodesy

GPS

Cosmogenic nuclide

Geochronology

Walker Lane

Eastern California shear zone

White Mountains fault zone

Lone Mountain fault

Basin and range

Plate tectonics

Geology, Structural

Geodesy

Geological time

Érosion des falaises de la région Provence-Alpes-Côte d’Azur : évolution et origine de la morphologie côtière en Méditerranée : télédétection, géochronologie, géomorphologie / Rocky cliff erosion in the region Provence-Alpes-Côte d’Azur : evolution and origin of the coastal morphology in the Mediterranean : remote sensing, geochronology, geomorphology

Giuliano, Jérémy

16 December 2015

L’intérêt croissant pour l’étude de la morphogénèse des côtes à falaises a permis de mieux appréhender les environnements méso/macrotidaux, mais en délaissant les environnements microtidaux. Pour cette raison, nous proposons d’étudier, à partir d’une approche exploratoire multi-échelle, la dynamique érosive des côtes à falaises en Méditerranée à travers l’exemple de la région Provence-Alpes-Côte d’Azur. Le choix de ce territoire s’est justifié en réponse à une problématique relative à la gestion des risques côtiers identifiée par le Conseil-Régional-PACA qui a financé ce travail doctoral. Les principaux objectifs visent à caractériser d’une part l’ampleur relative des occurrences érosives en fonction de la variabilité temporelle des forçages météo-climatiques, et d’autre part le degré du contrôle géologique sur la morphologie côtière. Toute la difficulté de l’étude réside donc dans l’optimisation des fenêtres d’observation afin de distinguer les comportements érosifs. Nous proposons donc de tester l’apport de quatre méthodes permettant de définir si l’érosion se produit de manière (1) continue à l’échelle annuelle (levés LiDAR embarqués depuis un bateau), (2) chronique à l’échelle séculaire (orthophotographies aériennes) et (3) exceptionnelle voir (4) catastrophique sur les temps propres à l’Holocène et au Quaternaire (datations aux cosmogéniques in situ 36Cl et analyses morphométriques). Au regard des résultats mesurés et interprétés, il apparaît que l’activité gravitaire produite au cours du XXe siècle (érosion moyenne de l’ordre du cm.an-1) est très faible par rapport aux environnements méso/macrotidaux / Increasing interest in studying rocky cliff coastline morphogenesis allowed a better understanding of meso/macrotidal environments, but let microtidal environments apart. Thus we propose studying the dynamic of cliff coastlines erosion in Mediterranean in the South-East of France, through a multi-scale explorative approach. This doctoral work was supported by the region Provence-Alpes-Côte d’Azur, which identified a problematic in relation with coastal hazard management. The main objectives aim at characterizing on one hand how the temporal variability of meteorologic and climatic forcings affects the magnitude of erosion, and on other hand to which extent the geological setting controls the coastline morphology. The great challenge of this work therefore consists in optimizing the observation range in order discriminate erosive behaviours. Thus we propose assessing the contribution of four methods in determining whether erosion takes place (1) continuously at annual scale (boat-borne laser scanning surveys), (2) chronic at secular scale (aerial orthophographies)and (3) exceptional even (4) catastrophic over the characteristic timescales of Holocene and Quaternary (cosmic ray exposure dating from in-situ 36Cl and morphometric analysis). The interpretation of the results shows that erosion rate observed through the XXth century (order of magnitude of cm.y-1) is very low compared to meso/macrotidal environments. However at timescales ranging from pluri-secular (0.29 ka BP) to pluri-millenar (6.8 ka BP), exceptional storms surges of +3 NGF could initiate an erosion process resulting in the formation of horizontal shore platforms.

Érosion

Falaise

Côte

Méditerranée

Géomorphologie

Climat

LiDAR

Scanner-laser

Photo-aérienne

Datation

Cosmonucléide

AMT

Morphométrie

Erosion

Cliff

Coast

Mediterranea

Geomorphology

Climate

LiDAR

Laser-scanning

Aerial-photography

Datation

Cosmogenic nuclide

AMT

Morphometry

名古屋大学における14C-AMS 研究の黎明期(1980-1990)

NAKAMURA, Toshio, 中村, 俊夫

03 1900

第23回名古屋大学年代測定総合研究センターシンポジウム平成22(2010)年度報告

宇宙線生成核種

放射性炭素年代測定

放射性炭素

超高感度質量分析

加速器質量分析

cosmogenic nuclide

Radiocarbon dating

Radiocarbon

Ultra-sensitive mass spectrometer

AMS

Histoire sismique des failles normales de la région du Lazio-Abruzzo (Italie) : implications sur la variabilité spatiale et temporelle du glissement sismique au sein d'un système de faille / Seismic history of normal fault in the Lazio-Abruzzo (Italy) : implications for the spatial and temporal variability of the seismic slip within a fault-system

Tesson, Jim

03 March 2017

La mesure et la modélisation des concentrations en $^{36}$Cl accumulé au sein d'un plan de faille normal permet d'estimer l'âge et le glissement des forts séismes passés ayant successivement exhumé ce plan de faille. Si cette méthode présente l'avantage de fournir des enregistrements paléo-sismologiques continus sur des périodes de temps relativement longues (10 000 à 20 000 ans), la modélisation de données repose jusqu’à présent sur un modèle direct qui permet difficilement d'attester de l'unicité du scenario proposé, et d'estimer précisément les incertitudes associées, et ne tient pas compte de l'histoire long-terme du plan de faille, avant son exhumation post-glaciaire (héritage). Nous avons développé dans un premier temps un nouveau modèle qui inclut l’histoire d'héritage, et mis en place une procédure d'inversion des données permettant de 1) déterminer l'ensemble des paramètres de l'histoire sismique d'exhumation, 2) d’attester de l'unicité du scénario proposé, et 3) de contraindre précisément ses incertitudes. Nous appliquons notre méthode d’inversion à 11 failles des Apennins Centraux et montrons une grande variabilité dans leur activité sismique au cours des derniers 10 000 à 45 000 ans, avec des accélérations représentant 2 à 20 fois la vitesse long-terme de la faille. Nos résultats suggèrent en particulier que l'activité sismique des failles des Apennins Centraux pourrait être contrôlée par les propriétés intrinsèques des failles (vitesse long-terme, longueur, segmentation, état de maturité structurale), ainsi que par des processus d'interactions visco-élastiques agissant entre les failles. / The use of $^{36}$Cl cosmogenic nuclide as a paleo-seismological tool to determine the seismic history of normal faults provide continuous records over the past 10 000 to 20 000 yrs. The modeling of the $^{36}$Cl concentrations measured at the surface of an exhumed fault-plane allows determining the age and the displacement of the past seismic events that successively exhumed the fault-plane. The available modeling approach is however unable to attest for the unicity of the inferred scenario, which makes the estimate of the associated uncertainties difficult. An other limitation concerns the long-term history of the fault-plane prior its post-glacial exhumation (inheritance), that is not fully accounted for in this model (Schlagenhauf et al., 2010). We have developed a reappraisal of this model that accounts for the inheritance history, and includes a procedure of data inversion to 1) determine all parameters of the exhumation history at once, 2) attest for the unicity of the proposed scenario, and 3) precisely determine the associated uncertainties. Applying our new modeling to 11 normal faults previously studied in Central Apennines, we observe a large variability of their seismic activity over the last 10 000 - 45 000 yrs, with slip-rate acceleration reaching 2-20 times their long-term slip-rate. In particular, our results suggest that the seismic activity of normal faults in Central Apennines could be controlled by intrinsic properties of the faults (such as their long-term slip-rate, fault-length, segmentation, state of structural maturity), and by visco-elastic stress transfers between faults.

Paléo-Sismologie

36Cl

Nucléide cosmogénique

Modélisation

Problème inverse

Failles normales

Apennins Centraux (Italie)

Super-Cycles

Interaction

Morpho-Tectonique

Failles actives

Méditerranée

Aléa sismique

Paleo-Seismology

36Cl

Cosmogenic nuclide

Modeling

Inverse problem

Normal fault

Central Apennines (Italy)

Supercycles

Interaction

Morpho-Tectonic

Active faults

Mediterranean

Seismic hazard