Signature des occupations protohistoriques et antiques dans l’évolution des paysages et dans la construction de la géographie humaine du massif du Mercantour (Alpes-Maritimes) / Traces of protohistoric and Roman settlement and the evoloution of landscapes and the construction of human geographies in the Mercantour massif (Alpes- Maritimes)

Sumera, Franck

27 March 2015

Les travaux archéologiques et paléoenvironnementaux conduits dans les Alpes du sud, témoignent de l’existence de pratiques pastorales continues depuis le Néolithique. Ces dernières auraient entraîné une ouverture constante du milieu dont résulterait la construction des paysages actuels. Les signaux renvoyés par l’archéologie, l’histoire et le paléoenvironnement concernant les pratiques d’élevage et les activités impactant les paysages depuis la Protohistoire sont revisités au travers d’une synthèse de l’état des connaissances. L’analyse est menée en recherchant les sources d’impacts paysagers et les articulations entre les pratiques pastorales, les territoires d’habitats et les zones d’échanges économiques. Une approche globale du territoire et des vestiges anthropiques est réalisée au travers de l’analyse du cadastre napoléonien et des couvertures ortho-photographiques. Les bases de données construites à partir de ces supports sont enrichies par l’intégration des données environnementales issues des bases SIG liées aux contextes environnementaux. L’ensemble livre un nouveau corpus de données archéologiques qui permet d’appréhender la diversité spatiale et qualitative des vestiges pastoraux. Trois études de cas apportent des informations sur le poids des occupations protohistoriques et antiques dans les étages subalpins. Deux d’entre elles permettent, d’aborder le thème de la construction des espaces territoriaux protohistoriques et antiques et de leurs évolutions postérieures. Un sanctuaire héroïque et naturiste gaulois situé à 1800 m. d’altitude et un sanctuaire de Col témoignent de l’importance de l’orographie dans la construction mentale des populations du Mercantour. / Archaeological and paleo-environmental research carried out in the Southern Alps attest to the existence of pastoral practices continuous from the Neolithic period. The latter brought about a constant opening-up of the environment which resulted in the formation of present-day landscapes. The signals sent back by archaeology, history and the paleo-environment concerning rearing practices and activities having had an impact on the landscape since the Iron Age are re-examined through a synthesis of the current state of knowledge. Analysis of existing documentation is used to ascertain sources of impact on the landscape and relationships between pastoral practices, settlement lands and areas of economic exchange. Comprehensive study of the territory and anthropic remains is carried out using the Napoleonic cadastral survey and orthophotographic coverage. The data bases built using these supports are enriched by the incorporation of environmental data taken from GIS bases connected to environmental contexts. This data set provides a new corpus of archaeological information which enables us to apprehend the spatial and qualitative diversity of pastoral remains. Three case-studies provide information concerning the weight of Iron Age and Roman occupation in the sub-Alpine floors. Two of these allow consideration of the construction of Iron Age and Roman territorial areas and their subsequent development. A Gallic sanctuary located at an altitude of 1800m, dedicated to hero and nature-worship, and another sanctuary located on a pass illustrate the importance of orography within the mental constructs of the Mercantour populations.

Évolution des paysages

Territoire

Protohistoire antiquité moyen-Âge

Mercantour

Alpes du sud

Sig

Evoloution of landscapes

Territorial areas

Protohistory antiquity middle ages

Mercantour

Southern Alps

Gis

Rock Avalanches on Glaciers: Processes and Implications

Reznichenko, Natalya

January 2012

This thesis examines the role of rock avalanches in tectonically active terrains including the effects of the deposits on glacier behaviour and their contribution to moraine formation. The chronologies of mountain glacier fluctuations, based on moraine ages, are widely used to infer regional climate change and are often correlated globally. In actively uplifting mountain ranges rock avalanches that travel onto the ablation zone of a glacier can reduce ice-surface melting by insulating the ice. This can cause buried ice to thicken due to slower ablation and can significantly alter the overall glacier mass balance. This glacier response to supraglacial rock avalanche deposits can confound apparent climatic signals extracted from moraine chronologies. This thesis investigates the processes through which rock avalanche deposits may affect glaciers and develops a new technique to identify the presence of rock avalanche debris in glacial moraines. From laboratory experiments on the effects of debris on ice ablation it is demonstrated that the rate of underlying ice ablation is controlled by diurnal cyclicity and is amplified at high altitude and in lower latitudes. The relatively low permeability of rock avalanche sediment in comparison with non-rock avalanche supraglacial debris cover contributes to the suppression of ablation, at least partly because it greatly reduces the advection of heat from rain water to the underlying ice. The laboratory findings are supplemented by field investigations of two recent rock avalanche deposits on glaciers in the Southern Alps of New Zealand. This work demonstrates that the rock avalanche deposits are very thick (10 m at Aoraki/Mt. Cook and 7m at Mt. Beatrice) and almost stopped the ablation of the overlying ice. This resulted in the formation of an ice-platform more than 30 m high. This led to a reduction of the existing negative mass balance of the affected Tasman and Hooker Glaciers. There was little noticeable alteration of the overall glacial regime due to the small scale of the debris covered area (4 and 1% of the ablation zones for the Tasman and Hooker Glaciers, respectively) but there is a significant contribution to supraglacial debris, which is passively transported toward the terminus. A conceptual model of the response of mountain valley glaciers to emplacement of extensive rock avalanche debris on the ablation zone has been proposed for the effect of this type of debris on terminal moraine formation based on enhanced ‘dumping’ of supraglacial sediments. A new technique has been developed to distinguish rock-avalanche-derived sediment from sediment of glacial origin, based on the sedimentary characteristics of the finest fraction. Examination of rock avalanche sediment under the Scanning Electron Microscope showed that finer particles tend to form strong clumps, which comprise many smaller (down to nanometre-scale) clasts, named here ‘agglomerates’. These agglomerates are present in the fine fraction of all examined rock avalanche deposits and absent in known non-rock-avalanche-derived glacial sediments. The agglomerates are characteristics of sediment produced under the high-stress conditions of rock avalanche emplacement and contrast with lower-stress process sub- and en-glacial environments. It is demonstrated that these agglomerates are present in some moraines in the Southern Alps of New Zealand that have been attributed to climate fluctuation. Consequently, this technique has the potential to resolve long-standing arguments about the role of rock avalanches in moraine formation, and to enhance the use of moraines in palaeoclimatological studies.

Rock avalanche

supraglacial rock avalanche

comminution

glacier

moraine

glacial sediment

ablation

debris-cover

glacial mass balance

advance

retreat

glacial regime

glacial geomorphology

aclimatic advance

microsedimentology

agglomerates

palaeoclimate

moraine chronology

rock-avalanche-driven advance

the Southern Alps of New Zealand

Norway

Geomorphic Hazard Analyses in Tectonically-Active Mountains: Application to the Western Southern Alps, New Zealand

Kritikos, Theodosios

January 2013

On-going population growth and urbanization increasingly force people to occupy environments where natural processes intensely affect the landscape, by way of potentially hazardous natural events. Tectonic plate boundaries, active volcanic regions and rapidly uplifting mountain ranges are prominent examples of geomorphically hazardous areas which today accommodate some of the world’s largest cities. These areas are often affected by more than one hazard such as volcanic eruptions, earthquakes, landslides, tsunamis, floods, storms and wildfires, which frequently interact with each other increasing the total impact on communities. Despite progress in natural hazards research over the last two decades, the increasing losses from natural disasters highlight the limitations of existing methodologies to effectively mitigate the adverse effects of natural hazards. A major limitation is the lack of effective hazard and risk assessments incorporating hazard interactions and cascade effects. Most commonly, the assessment of risks related to different hazards is carried out through independent analyses, adopting different procedures and time-space resolutions. Such approaches make the comparison of risks from different hazard sources extremely difficult, and the implicit assumption of independence of the risk sources leads to neglect of possible interactions among hazard processes. As a result the full hazard potential is likely to be underestimated and lead to inadequate mitigation measures or land-use planning. Therefore there is a pressing need to improve hazard and risk assessments and mitigation strategies especially in highly dynamic environments affected by multiple hazards. A prominent example of such an environment is the western Southern Alps of New Zealand. The region is located along an actively deforming plate boundary and is subject to high rates of uplift, erosion and orographically-enhanced precipitation that drive a range of interrelated geomorphic processes and consequent hazards. Furthermore, the region is an increasingly popular tourist destination with growing visitor numbers and the prospect for future development, significantly increasing societal vulnerability and the likelihood of serious impacts from potential hazards. Therefore the mountainous landscape of the western Southern Alps is an ideal area for studying the interaction between a range of interrelated geomorphic hazards and human activity. In an effort to address these issues this research has developed an approach for the analysis of geomorphic hazards in highly dynamic environments with particular focus on tectonically-active mountains using the western Southern Alps as a study area. The approach aims to provide a framework comprising the stages required to perform multi-hazard and risk analyses and inform land-use planning. This aim was approached through four main objectives integrating quantitative geomorphology, hazard assessments and GIS. The first objective was to identify the dominant geomorphic processes, their spatial distribution and interrelationships and explore their implications in hazard assessment and modelling. This was achieved through regional geomorphic analysis focusing on catchment morphometry and the structure of the drainage networks. This analysis revealed the strong influence and interactions between frequent landslides / debris-flows, glaciers, orographic precipitation and spatially-variable uplift rates on the landscape evolution of the western Southern Alps, which supports the need for hazard assessment approaches incorporating the interrelationships between different processes and accounting for potential event cascades. The second and third objectives were to assess the regional susceptibility to rainfall-generated shallow landslides and river floods respectively, as these phenomena are most often responsible for extensive damage to property and infrastructure, injury, and loss of lives in mountainous environments. To achieve these objectives a series of GIS-based models was developed, applied and evaluated in the western Southern Alps. Evaluation results based on historical records indicated that the susceptibility assessment of shallow landslides and river floods using the proposed GIS-based models is feasible. The output from the landslide model delineates the regional spatial variation of shallow landslide susceptibility and potential runout zones while the results from the flood modelling illustrate the hydrologic response of major ungauged catchments in the study area and identify flood-prone areas. Both outputs provide critical insights for land-use planning. Finally, a multi-hazard analysis approach was developed by combining the findings from the previous objectives based on the concepts of interaction and emergent properties (cascade effects) inherent in complex systems. The integrated analysis of shallow landslides, river floods and expected ground shaking from a M8 plate-boundary fault (Alpine fault) earthquake revealed the areas with the highest and lowest total susceptibilities. Areas characterized by the highest total susceptibility require to be prioritized in terms of hazard mitigation, and areas with very low total susceptibility may be suitable locations for future development. This doctoral research project contributes to the field of hazard research, and particularly to geomorphic hazard analyses in highly dynamic environments such as tectonically active mountains, aiming to inform land-use planning in the context of sustainable hazard mitigation.

debris-flow

exposure

fuzzy logic

geomorphic

GIS

hazard

hydrograph

landslide

land-use planning

mountains

multi-hazard analysis

New Zealand

quantitative geomorphology

river flood

runout

susceptibility assessment

system

western Southern Alps