Vegetation and climate reconstruction during the Last Interglacial Complex: the pollen record of Lake Ohrid (Albania/Fyrom), the oldest European lake

This thesis is focussed on the palaeonvironmental and climatic changes occurred during the period between 130 and 70 ka (including the whole Last Interglacial Complex), with the aims to investigate the long-term climate variability on environment, on the basis of high resolution pollen data from Lake Ohrid sediments (Albania/F.Y.R.O.M. border), the oldest lake in Europe and one of most ancient in the world. The climate reconstruction obtained from pollen data is based on a wider interval, 160-70 ka. Lake Ohrid is located in a key region at the confluence of central European and Mediterranean climate influences and as already demonstrated by previous studies, has an important role for the study of the climatic and environmental changes occurred during the millennia in the Balkan and European areas. The investigated pollen material comes from the sediments retrieved in spring 2013 in the frame of the project SCOPSCO (Scientific Collaboration on Past Speciation Conditions in Lake Ohrid) whose drilling was financed by the ICDP (International Continental Scientific Drilling Program). During the drilling campaign 6 parallel cores have been collected from the depocenter of Lake Ohrid obtaining an extraordinary composite sequence 569 m long (DEEP). The upper 247.8 m of DEEP core have been dated using tephrostratigraphic information and tuning of biogeochemical proxy data to orbital parameters and covers the last 637 ka. In the framework of this careful temporal establishment, an even more precise chronology for the Last Interglacial Complex, and in particular for the transition between MIS6 and 5, was obtained by comparing pollen data from the same period with other DEEP and Mediterranean proxies. This make Lake Ohrid extremely important because for the other records from Mediterranean and European area such chronological constrains are not available and so the chronologies are less precise. The pollen analysis results come from the uppermost 200 m of the DEEP core (covering the last 500 ka) and revealed a succession of non-forested and forested periods clearly connected with glacial–interglacial cycles of the marine isotope stratigraphy. Among the different glacial-interglacial cycle, the new high-resolution pollen stratigraphy of the Last Interglacial Complex shows the classical alternation of periods characterized by forest (interstadials, warm and wet periods) and open vegetation (stadials, cold and dry periods), clearly resembling the well-known vegetational and climate succession of other European records. Concerning the Last Interglacial (or Eemian, 128-112 ka, roughly equivalent to MIS5e), pollen analysis and climate quantitative reconstructions identify three key phases with a slight different timing, with an initial phase characterized by a sudden warming (propagation of mesophilous forests), then a decrease of temperatures associated with wet conditions (expansion of Carpinus betulus) and at the end a progressive establishment towards cold and dry conditions until the termination of Eemian at 112 ka, confirming what other previous studies on European records said, namely Eemian was not a stable period. Several abrupt events are in also identified, during the successive stadials and interstadials (Early Last Glacial), probably correlated to the succession of cold events recorded in the Greenland ice core records, associated to a weakening of the North Atlantic Meridional Overturning Circulation. This work provides a new pollen reference sequence for the Last Interglacial Complex in Europe and concerning climate reconstruction provides new information for a period (160-70 ka, from the last part of Riss Glaciation to the beginning of Würm Glaciation) still poorly investigated in Europe, mostly in the south (< 45° lat. N), where only one record has been studied for the whole interval, with high resolution time. According to my results, Lake Ohrid can be considered a key role site for the investigation of the climatic changes occurred in centennial and millennial scale in a region of mid-altitude between European and Mediterranean areas, providing furthermore new evidence for the connection between the Europe and Northern Hemisphere climate oscillations

Aligning and synchronization of MIS5 proxy records from Lake Ohrid (FYROM) with independently dated Mediterranean archives: implications for DEEP core chronology

The DEEP site sediment sequence obtained during the ICDP SCOPSCO project at Lake Ohrid was dated using tephrostratigraphic information, cyclostratigraphy, and orbital tuning through the marine isotope stages (MIS) 15-1. Although this approach is suitable for the generation of a general chronological framework of the long succession, it is insufficient to resolve more detailed palaeoclimatological questions, such as leads and lags of climate events between marine and terrestrial records or between different regions. Here, we demonstrate how the use of different tie points can affect cyclostratigraphy and orbital tuning for the period between ca. 140 and 70 ka and how the results can be correlated with directly/indirectly radiometrically dated Mediterranean marine and continental proxy records. The alternative age model presented here shows consistent differences with that initially proposed by Francke et al. (2015) for the same interval, in particular at the level of the MIS6-5e transition. According to this new age model, different proxies from the DEEP site sediment record support an increase of temperatures between glacial to interglacial conditions, which is almost synchronous with a rapid increase in sea surface temperature observed in the western Mediterranean. The results show how a detailed study of independent chronological tie points is important to align different records and to highlight asynchronisms of climate events. Moreover, Francke et al. (2016) have incorporated the new chronology proposed for tephra OH-DP-0499 in the final DEEP age model. This has reduced substantially the chronological discrepancies between the DEEP site age model and the model proposed here for the last glacial-interglacial transition

The interplay of climate change and human activity in the central Mediterranean region during the last millennia: the varved, multiproxy record of Lake Butrint (Albania)

Past Global Changes. Open Science Meeting (5º. 2017. Zaragoza)Butrint is a 21 m deep lagoon located at the Ionian Sea coast of Albania. Permanent water stratification led to the deposition of varved sediments during the last millennia. Variations in the thickness and/or presence of seasonal laminae (endogenic calcite, organic matter, and clay) indicate fluctuations in water salinity, bioproductivity, and runoff, resulting from the interplay of climate and anthropogenic forcing. The multi-proxy analysis (sedimentology, geochemistry, pollen and ostracods) of a 12 m long sediment core, supported by an age model through varve counting, radiocarbon and 137Cs dating, enables a precise reconstruction of environmental change in the central Mediterranean region during the last 4.5 cal kyrs BP. Additionally, the nearby archaeological site of Buthrotum, continuously populated from Greek times until the late 18th century AD, provides an exceptional record of human impact. Increasing siltation after the foundation of the city and subsequent farming and urbanization of the catchment led to the progressive isolation of the Butrint basin from an open bay to a restricted lagoon. Maximum clastic input at 500 AD likely coincides with the most intense farming during the Late Antiquity. Intervals of maximum water salinity and bioproductivity coincide with warmer conditions, such as the early Roman Warm Period (500 BC-0 AD) or the Medieval Climate Anomaly (800-1400 AD). Conversely, lower salinity, more oxic conditions, and higher runoff occurred during 1400-500 BC, Late Roman and Early Medieval times (0-800 AD), and during the Little Ice Age (1400-1800 AD). Ongoing research on microfacies and stable isotopes (δ 18O and δ 13C in authigenic calcite) allows a more precise reconstruction of the main hydrological changes in the lagoon during the last millennium. The sedimentary record of Lake Butrint demonstrates the complex interplay of climate variability and human impact in the recent evolution of coastal Mediterranean regions.Instituto Geológico y Minero de España, EspañaDepartamento de Ciencias de la Tierra y Física de la Materia Condensada, Universidad de Cantabria, EspañaInstitute of Geological Sciences and Oeschger Centre of Climate Change Research, University of Bern, SuizaDipartimento di Scienze della Terra, Sapienza University of Rome, ItaliaDepartment of Earth Sciences, University of Geneva, SuizaDepartamento de Procesos Geoambientales y Cambio Global, Instituto Pirenaico de Ecología, Consejo Superior de Investigaciones Científicas, EspañaDepartamento de Estratigrafía, Universidad Complutense de Madrid, EspañaDepartment of Geology and Mineralogy, University of Cologne, AlemaniaAlbanian Geological Survey, AlbaniaPeer reviewe

Mediterranean winter rainfall in phase with African monsoons during the past 1.36 million years

Mediterranean climates are characterized by strong seasonal contrasts between dry summers and wet winters. Changes in winter rainfall are critical for regional socioeconomic development, but are difficult to simulate accurately1 and reconstruct on Quaternary timescales. This is partly because regional hydroclimate records that cover multiple glacial–interglacial cycles2,3 with different orbital geometries, global ice volume and atmospheric greenhouse gas concentrations are scarce. Moreover, the underlying mechanisms of change and their persistence remain unexplored. Here we show that, over the past 1.36 million years, wet winters in the northcentral Mediterranean tend to occur with high contrasts in local, seasonal insolation and a vigorous African summer monsoon. Our proxy time series from Lake Ohrid on the Balkan Peninsula, together with a 784,000-year transient climate model hindcast, suggest that increased sea surface temperatures amplify local cyclone development and refuel North Atlantic low-pressure systems that enter the Mediterranean during phases of low continental ice volume and high concentrations of atmospheric greenhouse gases. A comparison with modern reanalysis data shows that current drivers of the amount of rainfall in the Mediterranean share some similarities to those that drive the reconstructed increases in precipitation. Our data cover multiple insolation maxima and are therefore an important benchmark for testing climate model performance

Vegetation and climate reconstruction during the last interglacial : the pollen record of Lake Ohrid (Republic of Macedonia) the oldest European lake

Cette thèse est centrée sur les changements paléoenvironnementaux et climatiques survenus dans le période entre 130 et 70 ka (Dernier Complexe Interglaciaire), pour étudier la variabilité du climat à long terme sur l'environnement, sur la base des données de pollen à haute résolution provenant des sédiments du lac Ohrid (Albanie / F.Y.R.O.M), le plus ancien lac d'Europe. La reconstruction du climat obtenue à partir des données polliniques est basée sur un intervalle plus large, 160-70 ka.Le matériel pollinique provient des sédiments prélevés en 2013, dans le cadre du projet SCOPSCO (Scientific Collaboration On Past Speciation Conditions in Lake Ohrid) dont le carottage a été financé par l'ICDP (International Continental Scientific Drilling Program). Pendant la campagne de carottage, 6 carottes parallèles ont été prélevées à partir de l’épicentre du lac, obtenant une séquence composite extraordinaire de 569 m (DEEP).Les 247.8 m supérieurs de la carotte DEEP ont été datés et ils couvrent les derniers 637 ka. Nous avons amélioré le modèle d’âge pour le Dernier Complexe Interglaciaire et en particulier pour la transition entre MIS6 et 5, en comparant les données polliniques avec d'autres proxies de la carotte DEEP et de la Méditerranée. Cela rend le lac Ohrid extrêmement important car pour les autres enregistrements de la région Européenne, de telles contraintes chronologiques ne sont pas disponibles.L'analyse des premiers 200 m de la carotte DEEP, couvrant les derniers 500 ka, a été étudiée avec une résolution de 1,6 ka. La séquence a révélé une alternance entre des ouvertures forestières et périodes boisées reflétant une cyclicité glaciaires-interglaciaires comparable à celle de la stratigraphie des isotopes marins. Parmi les différents cycles glaciaires-interglaciaires, l’analyse pollinique à haute résolution du Dernier Complexe Interglaciaire montre l'alternance classique de périodes caractérisées par la forêt (interstades, périodes chaudes et humides) et la végétation ouverte (stades, et périodes sèches), ressemblant clairement à la succession végétale et climatique bien connue des autres séquences européennes.Concernant le Dernier Interglaciaire (ou Eémien, 128-112 ka), l'analyse pollinique et les reconstructions quantitatives climatiques basées sur ces dernières identifient trois phases clés : une phase initiale caractérisée par un réchauffement soudain (propagation des forêts mésophiles), puis une diminution des températures associées à des conditions humides (expansion de Carpinus betulus) et à la fin un établissement progressif vers des conditions froides et sèches jusqu'à la fin de Eemian à 112 ka, confirmant l’hypothèse déjà avancée par plusieurs études antérieures basées sur des séquences polliniques européennes , à savoir que l’Eemien n'était pas une période climatiquement stable.D’autres changements climatiques sont également visibles dans la région du lac Ohrid entre 112-70 ka et probablement liés à la succession d'événements froids enregistrés dans les carottes de glace du Groenland, associé à un affaiblissement de l’AMOC (Atlantic Meridional Overturning Circulation).Ce travail a permis de fournir une nouvelle séquence de référence pollinique pour le Dernier Complexe Interglaciaire en Europe. Ce travail a également permis de quantifier les paléoclimats pour la période 160-70 ka, encore peu étudiée en Europe, principalement dans le sud (<45 ° lat. N), où un seul enregistrement a été étudié pour toute la période, avec une résolution temporelle élevée.Sur la base de ces résultats, le lac Ohrid apparait comme un site clé pour l'étude des changements climatiques survenus à une échelle centenaire et millénaire dans une région de moyenne altitude entre les régions européennes et méditerranéennes, fournissant en outre des nouvelles informations sur la connexion entre les oscillations climatiques de la région méditerranéenne et de l'Hémisphère du Nord.This thesis is focussed on the palaeonvironmental and climatic changes occurred during the period between 130 and 70 ka (Last Interglacial Complex), with the aims to investigate the long-term climate variability on environment, on the basis of high resolution pollen data from Lake Ohrid sediments (Albania/F.Y.R.O.M. border), the oldest lake in Europe. The climate reconstruction obtained from pollen data is based on a wider interval, 160-70 ka.The investigated pollen material comes from the sediments retrieved in spring 2013 in the frame of the project SCOPSCO (Scientific Collaboration On Past Speciation Conditions in Lake Ohrid) whose drilling was financed by the ICDP (International Continental Scientific Drilling Program). During the drilling campaign 6 parallel cores have been collected from the depocenter of Lake Ohrid obtaining an extraordinary composite sequence 569 m long (DEEP).The upper 247.8 m of DEEP core have been dated using tephrostratigraphic information and tuning of biogeochemical proxy data to orbital parameters and covers the last 637 ka. In the framework of this careful temporal establishment, an even more precise chronology for the Last Interglacial Complex, and in particular for the transition between MIS6 and 5, was obtained by comparing pollen data from the same period with other DEEP and Mediterranean proxies. This make Lake Ohrid extremely important because for the other records from Mediterranean and European area such chronological constrains are not available and so the chronologies are less precise.The pollen analysis results come from the uppermost 200 m of the DEEP core (covering the last 500 ka) and revealed a succession of non-forested and forested periods clearly connected with glacial–interglacial cycles of the marine isotope stratigraphy.Among the different glacial-interglacial cycle, the new high-resolution pollen stratigraphy of the Last Interglacial Complex shows the classical alternation of periods characterized by forest (interstadials, warm and wet periods) and open vegetation (stadials, cold and dry periods), clearly resembling the well-known vegetational and climate succession of other European records.Concerning the Last Interglacial (or Eemian, 128-112 ka, roughly equivalent to MIS5e), pollen analysis and climate quantitative reconstructions identify three key phases with a slight different timing, with an initial phase characterized by a sudden warming (propagation of mesophilous forests), then a decrease of temperatures associated with wet conditions (expansion of Carpinus betulus) and at the end a progressive establishment towards cold and dry conditions until the termination of Eemian at 112 ka, confirming what other previous studies on European records said, namely Eemian was not a stable period.Several abrupt events are in also identified, during the successive stadials and interstadials (Early Last Glacial), probably correlated to the succession of cold events recorded in the Greenland ice core records, associated to a weakening of the North Atlantic Meridional Overturning Circulation.This work provides a new pollen reference sequence for the Last Interglacial Complex in Europe and concerning climate reconstruction provides new information for a period (160-70 ka, from the last part of Riss Glaciation to the beginning of Würm Glaciation) still poorly investigated in Europe, mostly in the south (< 45° lat. N), where only one record has been studied for the whole interval, with high resolution time.According to my results, Lake Ohrid can be considered a key role site for the investigation of the climatic changes occurred in centennial and millennial scale in a region of mid-altitude between European and Mediterranean areas, providing furthermore new evidence for the connection between the Europe and Northern Hemisphere climate oscillations