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Diese Arbeit stellt die Ergebnisse der stratigraphischen und tektonischen Aufnahme des Blattes 5827 Maßbach vor. Sie erfolgte im Rahmen der geologischen Landesaufnahme von Bayern 1:25.000 sowie im Auftrag des Bayerischen Landesamts für Umwelt und beruht auf einer geologischen Detailkartierung im Maßstab 1:10.000. Die wesentlichen Ergebnisse sind folglich in der Geologischen Karte 1:25.000 und in der Strukturkarte 1:50.000 dargestellt.
Zur Aufgabenstellung gehörten ebenfalls eine moderne Erfassung und Darstellung der Schichtenfolge unter stratigraphischen und faziellen Gesichtspunkten sowie die Aufnahme und Interpretation geologischer Strukturen und deren Einbindung in den regionalen Rahmen (Anlage 7). Dieser Arbeit kommt somit nicht nur akademisches Interesse zu. Vielmehr ist sie auch für angewandte Fachbereiche wesentlich: u.a. für Hydrogeologie, Geothermie oder für Fragen der Raumplanung.
Das Kartenblatt 5827 Maßbach liegt im nordöstlichen Unterfranken im Norden Bayerns. Die nächstgrößere Stadt, südlich des Blattgebietes, ist Schweinfurt. Das Gebiet zeigt einen Ausschnitt des südwestdeutschen Schichtstufenlandes innerhalb der Südwestdeutschen Großscholle sensu CARLÉ (1955). Geomorphologen rechnen es der Hochfläche der „Schweinfurter Rhön“ zu. Ein naturräumlicher Überblick über Geographie, Geologie, Hydrogeologie, Rohstoffgeologie und Bodenkunde sowie ein erdgeschichtlicher Abriss werden im ersten Teil der Arbeit (S. 2–15) gegeben.
Die Kartierung erfolgte als Lesesteinkartierung; denn die Aufschlussverhältnisse waren schlecht. Auch existieren nur wenige auswertbare Bohrungen. Vor diesem Hintergrund stellt der zweite Teil der Arbeit die zu Tage ausstreichende mesozoische Schichtenfolge vor (S.16–76). Die Schichtenfolge gehört ausschließlich in die Trias, reicht vom Unteren Muschelkalk bis zum Unteren Gipskeuper und umfasst etwa 270 bis 280 Meter. Hinzu kommen verschiedene quartäre Sedimente geringer Mächtigkeit.
Der dritte Teil der Arbeit (S. 77–95) befasst sich mit den Lagerungsverhältnissen und der tektonischen Zergliederung des Gebietes. Das tektonische Relief auf Blatt 5827 Maßbach misst etwa 260–270 m. Prägendes Element ist der Kissingen–Haßfurter Sattel, dessen Sattelachse das Blattgebiet von NW nach SE quert. Im SW–Quadranten ist die in Südwestdeutschland bedeutsame Kissingen–Haßfurter–Störungszone wirksam
Im regionalen Rahmen verbinden sich eine Vielzahl von nachgewiesenen tektonischen Elementen zu sich überlagernden tektonischen Strukturen. Deren Ausgestaltung verlief mehrphasig und sie erhielten ihre heute bestehende Form wohl durch die Fernwirkung der alpidischen Orogenese. Die Anlage der tektonischen Hauptelemente hingegen reicht wahrscheinlich bis in die ausgehende variszidische Gebirgsbildung zurück. Die zusammen-fassende Analyse und Darstellung der Ergebnisse führt in dieser Arbeit zur Einarbeitung des Blattes 5827 Maßbach in den regionalen stratigraphischen wie tektonischen Rahmen der umliegenden Blätter der GK 25.
Bei der Cu-Zn-Lagerstätte bei Kupferberg, 10 km nordöstlich von Kulmbach, handelt es sich um Bayerns größten, historischen Buntmetallabbau. Der etwa 4 km lange Zug einzelner, stratiformer Erzlinsen befindet sich im Nordwesten in der parautochthonen Randschiefer Formation und im Südosten in der Prasinit-Phyllit Formation, die ein Teil der allochthonen Münchberger Gneismasse ist. Bisherige Versuche, die Genese der Lagerstätte zu erklären, scheiterten daran, den versatzlosen Übertritt einer stratiformen Lagerstätte über eine regional bedeutende Störungszone zu erklären.
U-Pb Zirkondatierungen an mafischen und felsischen Vulkaniten im Umfeld der Lagerstätte bestätigten das Bild eines kambrisch-ordovizischen Extensionsvulkanismus. Das Fehlen von N-MORB-ähnlichen geochemischen Signaturen in den untersuchten Proben der gesamten südwestlichen, saxothuringischen Vogtland Synklinale deutet auf eine gescheiterte Riftbildung am Nordrand Gondwanas hin und setzt somit den geotektonischen Rahmen für die Ablagerung der Wirtsformation(en).
Die Cu-Zn-Vererzung selbst liegt hier im Wesentlichen als Vergesellschaftung von Pyrit, Chalkopyrit, Sphalerit, Quarz und Kalzit in kohlenstoffreichem Tonschiefer vor. Die verschiedenen Untersuchungen an den beiden Erzlinsen zeigten, dass in der „St. Veits“ Erzlinse eine syngenetische Pyrit-Anreicherung mit charakteristisch niedrigen Co/Ni-Verhältnissen (ø = 3,7) vorliegt. Darüber hinaus konnte dort noch mindestens eine hydrothermale Pyrit-Generation (Co/Ni-Verhältnis ca. 35) nachgewiesen werden, die nur dort auftritt, wo auch Chalkopyrit angereichert ist und deutlich höhere Co/Ni-Verhältnisse aufweist (ø = 35). Die Ermittlung der Cu-Isotopenverhältnisse des Chalkopyrits zeigte ein δ65Cu-Spektrum von -0,26 bis 0,36 ‰, was stark für eine hydrothermale Anreicherung unter hohen (>250 °C) Temperaturbedingungen spricht.
Während sich die Erzlinsen in der Randschiefer und Prasinit-Phyllit Formation hinsichtlich ihrer Sulfid-Mineralogie so ähnlich sind, dass sie bisher immer als eine Lagerstätte angesprochen wurden, erbrachte ein statistischer Vergleich der beiden δ34S-Datensätze, dass es sich hier nur mit einer Wahrscheinlichkeit von ca. 2 % um Stichproben der gleichen Grundgesamtheit handelt. Entsprechend liegen innerhalb der Kupferberger Lagerstätte zwei unterschiedliche Schichten, reich an syngenetischem Pyrit, vor. Die Tatsache, dass das δ34S-Spektrum potentieller Schwefelquellen für die hydrothermale Chalkopyrit-Mineralisation theoretisch sehr groß, de facto aber mit dem δ34S-Spektrum der syngenetischen Sulfidanreicherung fast identisch ist (δ34S = 3,2 ± 0,6 ‰ bzw. δ34S = 3,1 ± 0,9 ‰), spricht für eine schichtinterne Sulfidmobilisierung.
Aus den hier erbrachten Ergebnissen wird ein genetisches Modell für die Kupferberger Lagerstätte geschlussfolgert, in dem jeweils eine der zahlreichen sedimentären, Pyrit-reichen Schichten aus der Randschiefer und der Prasinit-Phyllit Formation bei der Überschiebung der Münchberger Gneismasse tektonisch in Kontakt gebracht wurden. Im Zuge eben dieser Raumnahme der allochthonen Masse wurden Teile der Randschiefer Formation unter Grünschiefer-fazielle Bedingungen gebracht. Dabei kam es sowohl zur Freisetzung von Buntmetallen, die vorher zum Großteil in Pyrit gebunden waren, als auch zur Entwässerung der umliegenden Tonschiefer. Durch die überlagernden, impermeablen metamorphen Decken wurde das entstandene metallreiche Fluid an der Überschiebungsbahn kanalisiert. Durch den Druckabfall in der Spröde-Duktil-Übergangszone kam es zum Sieden des aufsteigenden Fluids, was zur Ausfällung der Sulfide führte. Die Bildung bedeutender Erzlinsen erfolgte vor allem dort, wo das übersättigte Fluid auf Pyrit-reiche Schwarzschiefer bzw. Phyllite traf. Da die Abbauwürdigkeit dieser Erzlinsen im Wesentlichen auf die epigenetische Überprägung im Zuge der Deckenüberschiebung zurückzuführen ist, handelt es sich bei der Kupferberger Cu-Zn-Vererzung um eines der seltenen Beispiele für eine tatsächliche metamorphogene bzw. syntektonische Buntmetalllagerstätte.
Environmental interlinked problems such as human-induced land cover change, water scarcity, loss in soil fertility, and anthropogenic climate change are expected to affect the viability of agriculture and increase food insecurity in many developing countries. Climate change is certainly the most serious of these challenges for the twenty-first century. The poorest regions of the world – tropical West Africa included – are the most vulnerable due to their high dependence on climate and weather sensitive activities such as agriculture, and the widespread poverty that limits the institutional and economic capacities to adapt to the new stresses brought about by climate change. Climate change is already acting negatively on the poor smallholders of tropical West Africa whose livelihoods dependent mainly on rain-fed agriculture that remains the cornerstone of the economy in the region. Adaptation of the agricultural systems to climate change effects is, therefore, crucial to secure the livelihoods of these rural communities. Since information is a key for decision-making, it is important to provide well-founded information on the magnitude of the impacts in order to design appropriate and sustainable adaptation strategies.
Considering the case of agricultural production in the Republic of Benin, this study aims at using large-scale climatic predictors to assess the potential impacts of past and future climate change on agricultural productivity at a country scale in West Africa. Climate signals from large-scale circulation were used because state-of-the art regional climate models (RCM) still do not perfectly resolve synoptic and mesoscale convective processes. It was hypothesised that in rain-fed systems with low investments in agricultural inputs, yield variations are widely governed by climatic factors. Starting with pineapple, a perennial fruit crops, the study further considered some annual crops such as cotton in the group of fibre crops, maize, sorghum and rice in the group of cereals, cowpeas and groundnuts belonging to the legume crops, and cassava and yams which are root and tuber crops. Thus the selected crops represented the three known groups of photosynthetic pathways (i.e. CAM, C3, and C4 plants).
In the study, use was made of the historical agricultural yield statistics for the Republic of Benin, observed precipitation and mean near-surface air temperature data from the Climatic Research Unit (CRU TS 3.1) and the corresponding variables simulated by the regional climate model (RCM) REMO. REMO RCM was driven at its boundaries by the global climate model ECHAM 5. Simulations with different greenhouse gas concentrations (SRES-A1B and B1 emission scenarios) and transient land cover change scenarios for present-day and future conditions were considered. The CRU data were submitted to empirical orthogonal functions analysis over the north hemispheric part of Africa to obtain large-scale observed climate predictors and associated consistent variability modes. REMO RCM data for the same region were projected on the derived climate patterns to get simulated climate predictors. By means of cross-validated Model Output Statistics (MOS) approach combined with Bayesian model averaging (BMA) techniques, the observed climate predictors and the crop predictand were further on used to derive robust statistical relationships. The robust statistical crop models perform well with high goodness-of-fit coefficients (e.g. for all combined crop models: 0.49 ≤ R2 ≤ 0.99; 0.28 ≤ Brier-Skill-Score ≤ 0.90).
Provided that REMO RCM captures the main features of the real African climate system and thus is able to reproduce its inter-annual variability, the time-independent statistical transfer functions were then used to translate future climate change signal from the simulated climate predictors into attainable crop yields/crop yield changes. The results confirm that precipitation and air temperature governed agricultural production in Benin in general, and particularly, pineapple yield variations are mainly influenced by temperature. Furthermore, the projected yield changes under future anthropogenic climate change during the first-half of the 21st century amount up to -12.5% for both maize and groundnuts, and -11%, -29%, -33% for pineapple, cassava, and cowpeas respectively. Meanwhile yield gain of up to +10% for sorghum and yams, +24% for cotton, and +39% for rice are expected. Over the time period 2001 – 2050, on average the future yield changes range between -3% and -13% under REMO SRES–B1 (GHG)+LCC, -2% and -11% under REMO SRES–A1B (GHG only),and -3% and -14% under REMO SRES–A1B (GHG)+LCC for pineapple, maize, sorghum, groundnuts, cowpeas and cassava. In the meantime for yams, cotton and rice, the average yield gains lie in interval of about +2% to +7% under REMO SRES–B1 (GHG)+LCC, +0.1% and +12% under REMO SRES–A1B (GHG only), and +3% and +10% under REMO SRES–A1B (GHG)+LCC. For sorghum, although the long-term average future yield depicts a reduction there are tendencies towards increasing yields in the future. The results also reveal that the increases in mean air temperature more than the changes in precipitation patterns are responsible for the projected yield changes. As well the results suggest that the reductions in pineapple yields cannot be attributed to the land cover/land use changes across sub-Saharan Africa. The production of groundnuts and in particular yams and cotton will profit from the on-going land use/land cover changes while the other crops will face detrimental effects.
Henceforth, policymakers should take effective measures to limit the on-going land degradation processes and all other anthropogenic actions responsible for temperature increase. Biotechnological improvement of the cultivated crop varieties towards development of set of seed varieties adapted to hotter and dry conditions should be included in the breeding pipeline programs. Amongst other solutions, application of appropriate climate-smart agricultural practices and conservation agriculture are also required to offset the negative impacts of climate change in agriculture.
Considering its social, economic and natural conditions the Mediterranean Area is a highly vulnerable region by designated affections of climate change. Furthermore, its climatic characteristics are subordinated to high natural variability and are steered by various elements, leading to strong seasonal alterations. Additionally, General Circulation Models project compelling trends in specific climate variables within this region. These circumstances recommend this region for the scientific analyses conducted within this study. Based on the data of the CMIP3 database, the fundamental aim of this study is a detailed investigation of the total variability and the accompanied uncertainty, which superpose these trends, in the projections of temperature, precipitation and sea-level pressure by GCMs and their specific realizations. Special focus in the whole study is dedicated to the German model ECHAM5/MPI-OM. Following this ambition detailed trends and mean values are calculated and displayed for meaningful time periods and compared to reanalysis data of ERA40 and NCEP. To provide quantitative comparison the mentioned data are interpolated to a common 3x3° grid.
The total amount of variability is separated in its contributors by the application of an Analysis of Variance (ANOVA). For individual GCMs and their ensemble-members this is done with the application of a 1-way ANOVA, separating a treatment common to all ensemble-members and variability perturbating the signal given by different initial conditions. With the 2-way ANOVA the projections of numerous models and their realizations are analysed and the total amount of variability is separated into a common treatment effect, a linear bias between the models, an interaction coefficient and the residuals.
By doing this, the study is fulfilled in a very detailed approach, by considering yearly and seasonal variations in various reasonable time periods of 1961-2000 to match up with the reanalysis data, from 1961-2050 to provide a transient time period, 2001-2098 with exclusive regard on future simulations and 1901-2098 to comprise a time period of maximum length. The statistical analyses are conducted for regional-averages on the one hand and with respect to individual grid-cells on the other hand. For each of these applications the SRES scenarios of A1B, A2 and B1 are utilized. Furthermore, the spatial approach of the ANOVA is substituted by a temporal approach detecting the temporal development of individual variables. Additionally, an attempt is made to enlarge the signal by applying selected statistical methods.
In the detailed investigation it becomes evident, that the different parameters (i.e. length of temporal period, geographic location, climate variable, season, scenarios, models, etc…) have compelling impact on the results, either in enforcing or weakening them by different combinations. This holds on the one hand for the means and trends but also on the other hand for the contributions of the variabilities affecting the uncertainty and the signal. While temperature is a climate variable showing strong signals across these parameters, for precipitation mainly the noise comes to the fore, while for sea-level pressure a more differentiated result manifests. In turn, this recommends the distinguished consideration of the individual parameters in climate impact studies and processes in model generation, as the affecting parameters also provide information about the linkage within the system.
Finally, an investigation of extreme precipitation is conducted, implementing the variables of the total amount of heavy precipitation, the frequency of heavy-precipitation events, the percentage of this heavy precipitation to overall precipitation and the mean daily intensity from events of heavy precipitation. Each time heavy precipitation is defined to exceed the 95th percentile of overall precipitation. Consecutively mean values of these variables are displayed for ECHAM5/MPI-OM and the multi-model mean and climate sensitivities, by means of their difference between their average of the past period of 1981-2000 and the average of one of the future periods of 2046-2065 or 2081-2100. Following this investigation again an ANOVA is conducted providing a quantitative measurement of the severity of change of trends in heavy precipitation across several GCMs.
Besides it is a difficult task to account for extreme precipitation by GCMs, it is noteworthy that the investigated models differ highly in their projections, resulting partially in a more smoothed and meaningful multi-model mean. Seasonal alterations of the strength of this behaviour are quantitatively supported by the ANOVA.
The eminent importance of snow cover for climatic, hydrologic, anthropogenic, and economic reasons has been widely discussed in scientific literature. Up to 50% of the Northern Hemisphere is covered by snow at least temporarily, turning snow to the most prevalent land cover types at all. Depending on regular precipitation and temperatures below freezing point it is obvious that a changing climate effects snow cover characteristics fundamentally. Such changes can have severe impacts on local, national, and even global scale. The region of Central Asia is not an exception from this general rule, but are the consequences accompanying past, present, and possible future changes in snow cover parameters of particular importance. Being characterized by continental climate with hot and dry summers most precipitation accumulates during winter and spring months in the form of snow. The population in this 4,000,000 km² vast area is strongly depending on irrigation to facilitate agriculture. Additionally, electricity is often generated by hydroelectric power stations. A large proportion of the employed water originates from snow melt during spring months, implying that changes in snow cover characteristics will automatically affect both the total amount of obtainable water and the time when this water becomes available. The presented thesis explores the question how the spatial extent of snow covered surface has evolved since the year 1986. This investigation is based on the processing of medium resolution remote sensing data originating from daily MODIS and AVHRR sensors, thus forming a unique approach of snow cover analysis in terms of temporal and spatial resolution. Not only duration but also onset and melt of snow coverage are tracked over time, analyzing for systematic changes within this 26 years lasting time span. AVHRR data are processed from raw Level 1B orbit data to Level 3 thematic snow cover products. Both, AVHRR and MODIS snow maps undergo a further post-processing, producing daily full-area mosaics while completely eliminating inherent cloud cover. Snow cover parameters are derived based on these daily and cloud-free time series, allowing for a detailed analysis of current status and changes. The results confirm the predictions made by coarse resolution predictions from climate models: Central Asian snow cover is changing, posing new challenges for the ecosystem and future water supply. The changes, however, are not aimed at only one direction. Regions with decreasing snow cover exist as well as those where the duration of snow cover increases. A shift towards earlier snow cover start and melt can be observed, posing a serious challenge to water management authorities due to a changed runoff regime.
The discontinuous mountain permafrost zone is characterized by its heterogeneous distribution of frozen ground and a small-scale variability of the ground thermal regime. Large parts of these areas are covered by glacial till and sediments that were exposed after the recession of the glaciers since the 19th century. As response to changed climatic conditions permafrost-affected areas will lose their ability as sediment storage and on the contrary, they will act as source areas for unconsolidated debris. Along with modified precipitation patterns the degradation of the discontinuous mountain permafrost zone will (temporarily)
increase its predisposition for mass movement processes and thus has to be monitored in a differentiated way.
Therefore, the spatio-temporal dynamics of frozen ground are assessed in this study based on results obtained in three glacier forefields in the Engadin (Swiss Alps) and at the Zugspitze (German Alps). Sophisticated techniques are required to uncover structural differences in the subsurface. Thus, the applicability of advanced geophysical methods is tested for alpine environments and proved by the good 3D-delineation of a permafrost body and by the detection of detailed processes in the active layer during snow melt. Electrical resistivity tomography (ERT) approaches (quasi-3D, daily monitoring) reveal
their capabilities to detect subsurface resistivity changes both, in space and time. Processes and changes in regard to liquid water content and ice content are observed to exist at short distances even though the active layer is not subject to a considerable thickening
over the past 7 years. The stability of the active layer is verified by borehole temperature data. No synchronous
trend is recognized in permafrost temperatures and together with multi-annual electrical resistivity data they indicate degradation and aggradation processes to occur at the same time. Different heat transfer mechanisms, especially during winter, are recognized by means of temperature sensors above, at, and beneath the surface. Based on surface and borehole temperature data the snow cover is assessed as the major controlling factor for the thermal regime on a local scale. Beyond that, the debris size of the substrate, which modifies the snow cover and regulates air exchange processes above the ground, plays a crucial role as an additional buffer layer. A fundamental control over the stability of local permafrost patches is attributed to the ice-rich transient layer at the base of the active layer. The refreezing of melt water in spring is illustrated with diurnal ERT monitoring data from glacier forefield Murtèl.
Based on these ERT and borehole temperature data a conceptual model of active layer processes between autumn and spring is developed. The latent heat that is inherent in the transient layer protects the permafrost beneath from additional energy input from the surface as long as the refreezing of melt water in spring prevails and sufficient ice is build up each spring. Permafrost sites without a transient layer show considerably higher
temperatures at their table and are more prone to degradation in the years and decades ahead. As main investigation area a glacier forefield beneath the summits of Piz Murtèl and Piz Corvatsch in the Swiss Engadin was chosen. It is located west of the well-known
rock glacier Murtèl. Here, a permafrost body inside and adjacent to the lateral moraine was investigated and could be delineated very well. In the surrounding glacier forefield no further indications of permafrost occurrence could be made. Geophysical data and temperature values from the surface and from a permafrost borehole were compared with long-term data from proximate glacier forefield Muragl (Engadin). Results from both
sites show a considerable stability of the active layer depth in summer while at the same time geophysical data demonstrate annual changes in the amount of liquid water content and ice content in the course of years.
A third investigation area is located in the German Alps. The Zugspitzplatt is a high mountain valley with considerably more precipitation and thicker snow cover compared to both Swiss sites. In close proximity to the present glacier and at a large talus slope beneath the summit crest ground ice could be observed. The high subsurface resistivity values and comparable data from existing studies at the Zugspitze may indicate the presence of sedimentary ice in the subsurface of the karstified Zugspitzplatt. Based on these complementary data from geophysical and temperature measurements as
well as geomorphological field mapping the development of permafrost in glacier forefields under climate change conditions is analyzed with cooperation partners from the SPCC project. Ground temperature simulations forced with long-term climatological data are modeled to assess future permafrost development in glacier forefield Murtèl. Results suggest that permafrost is stable as long as the ice-rich layer between the active layer and
the permafrost table exists. After a tipping point is reached, the disintegration of frozen ground starts to proceed rapidly from the top.
In the central Alps permafrost can be expected above 2300 m a.s.l., at altitudes where mean annual air temperatures are below -1 °C. Isolated permafrost occurrences can be detected in north-exposed talus slopes, far below the timberline, where mean annual air temperatures are positive. Driving factors are assumed to be a low income of solar radiation, a thick organic layer with high insulation capacities as well as the thermally induced chimney effect.
Aim of this study is to achieve a deeper understanding of the factors determining the site-specific thermal regime, as well as the spatially limited and temporally highly variable permafrost occurrences in vegetated talus slopes.
Three supercooled talus slopes in the Swiss Alps were chosen for investigation. Substantially different characteristics were a central criterion in the selection of study sites. Located in the Upper Engadin, climatic conditions, altitude as well as dimensions of the talus slopes are comparable for the study sites Val Bever and Val Susauna; major differences are rooted in the nature of talus substrate and in humus- and vegetation distribution. Characteristics of the Brüeltobel site, located in the Appenzeller Alps, diverge with regard to climatic conditions, altitude and dimensions of the talus slope; humus- and vegetation compositions are comparable to the Val Susauna site.
Confirmation and characterisation of ground ice is accomplished by the application of electrical resistivity and seismic refraction tomography. The estimation of the spatial permafrost distribution is based on quasi-3D resistivity imaging. For the confirmation of permafrost and the analysis of its temporal variability electrical resistivity monitoring arrays were constructed and installed at all study sites, to allow year-round measurements. In addition to resistivity monitoring, the – up to now – first seismic refraction tomography winter monitoring was conducted at the Val Susauna to analyse the permafrost evolution during the winter half-year. Investigations of the ground thermal regime were based on the analysis of temperature logger data. Besides recording air- and ground surface temperatures, focus was set on the temperature evolution in vents and in the organic layer. To analyse the relationship between permafrost distribution on the one hand and humus- and vegetation distribution on the other hand, an extensive mapping of humus characteristics and vegetation composition was conducted at Val Susauna.
The existence of permafrost could be proven at all study sites. Spatially, permafrost bodies show a narrow transition to neighbouring, unfrozen areas. As observed at Val Susauna, the permafrost distribution strongly correlates with areas with exceptionally thick organic layer, high percentages of mosses and lichens in the undergrowth and dwarf grown trees. The temporal variability of permafrost has proven to be exceptionally high, with the magnitude of seasonal variations distinctly exceeding intra-annual changes. Thereby, the winter season is characterised by a significant supercooling. During snowmelt a growth in volumetric ice content is induced by refreezing of percolating meltwater on the supercooled talus.
The results confirmed the fundamental influence of the chimney effect on the existence and temporal variability of permafrost in talus slopes. Divergences in the effectiveness of the thermal regime were detected between the study sites. These are based on differences in the nature of talus material, humus characteristics and vegetation composition.
During summer, the organic material is usually dry at the daytime, inducing a high insulation capability and a protection of the subsurface against high atmospheric temperatures. Bouldery talus slopes typically show an organic layer that is fragmented by large boulders, which induces a strongly reduced insulation capability and allows an efficient heat exchange by convective airflow and percolating precipitation water. In the winter half-year, the thermal conductivity of the organic layer increases massively under moist or frozen conditions, allowing an efficient, conductive cooling of the talus material. The convective cooling in bouldery talus slopes affects an earlier onset and a higher magnitude of supercooling than under consistent humus conditions. Here, conductive heat flow is dominant and the cooling in autumn is buffered by a prolonged zero curtain. The snow cover has proven to be incapable of prohibiting an efficient supercooling of the talus slope in winter, almost independent from thickness.