Evaluation and application of dialysis porewater samplers for microbiological studies at sediment-water interfaces

The equilibrium diffusion technique has become a valuable tool for ecological and biogeochemical studies in aquatic environments. In sediment ecosystems, changes in concentration of microbial metabolites with increasing depth can be determined dependably and reproducibly with this technique. Since the permeation characteristics of the membranes employed are crucial, selecting the proper membrane requires knowledge about its behavior under conditions which prevail in the natural environment. Thirteen polymer sheets were evaluated comparing permeation terms for biogeochemically relevant solutes, biodegradability, and mechanical strength. Cellulose-based dialysis membranes are most satisfactory when employed in low temperature anoxic environments. For this membrane, correction terms were calculated to account for diffusion losses during retrieval and sampling. Optimal incubation times can now be predicted from experimentally determined permeation coefficients for several porewater solutes. Dialysis porewater samplers (DPS) have been successfully applied during more than 100 independent experiments for the collection of interstitial water from surface sediments. DPS were used for water depths as deep as 290 meters.     

Erwiderung zu dem Aufsatz von Dr. Georgi: Das neue Absolut-Pyrheliometer von Prof. K. Wegener

Ohne Zusammenfassung     

High‐Arctic climate conditions for the last 7000 years inferred from multi‐proxy analysis of the Bliss Lake record,North Greenland

The Arctic is more vulnerable to climate change than are mid latitudes. Therefore, palaeolimnological studies from the High Arctic are important in providing insights into the dynamics of the climate system. Here we present a multi‐proxy study from one of the world's northernmost lakes: Bliss Lake, Peary Land, Greenland. The early Holocene (10 850–10 480 cal. a BP) is characterized by increased erosion and gradually more marine conditions. Full marine conditions developed from 10 480 cal. a BP until the lake was isolated at 7220 cal. a BP. From its marine isolation at 7220 cal. a BP Bliss Lake becomes a lacustrine environment. Evidence from geochemical proxies (δ¹³C and total organic carbon) suggests that warmer conditions prevailed between 7220 and 6500 cal. a BP, corresponding to the Holocene thermal maximum, and from 3300 until 910 cal. a BP. From 850 to 500 cal. a BP colder climate conditions persisted. The transition from warmer to colder climate conditions taking place around 850 cal. a BP may be associated with the transition from the Medieval Warm Period to the Little Ice Age. Copyright © 2011 John Wiley & Sons, Ltd.     

Morphological analysis of the drainage system in the Eastern Alps

We study the morphology of the major rivers draining the Eastern Alps to test whether the active tectonics of this part of the orogen is reflected in the shape of channel profiles of the river network. In our approach we compare channel profiles measured from digital elevation models with numerically modelled channel profiles using a stream power approach. It is shown that regions of high stream power coincide largely with regions of highest topography and largest uplift rates, while the forelands and the Pannonian Basin are characterised by a significantly lower stream power. From stream power modelling we conclude that there is young uplift at the very east of the Eastern Alps, in the Bohemian Massif and in the Pohorje Range. The impact of the Pleistocene glaciations is explored by comparing properties of rivers that drain in proximal and distal positions relative to the ice sheet during the last glacial maximum. Our analysis shows that most knick points, wind gaps and other non-equilibrium features of catchments covered by ice during the last glaciations (Salzach, Enns) can be correlated with glacial processes. In contrast the ice free catchments of the Mur and Drava are characterized by channels in morphological equilibrium at the first approximation and are showing only weak evidence of the strong tectonic activity within these catchments. Finally, the channel profiles of the Adige and the divide between the upper Rhine and Danube catchments differ significantly from the other catchments. We relate this to the fact that the Adige and the Rhine respond to different base levels from the remainder of the Eastern Alps: The Adige may preserve a record from the Messininan base level change and the Rhine is subject to the base level lowering in the Rhine Graben.     

Tectonics and sedimentation in the Fohnsdorf-Seckau Basin (Miocene, Austria): from a pull-apart basin to a half-graben

The Miocene intramontane Fohnsdorf-Seckau Basin is situated at the junction of the sinistral Mur-Mürz-fault system and the dextral Pöls-Lavanttal fault system. The basin comprises a 2,400-m-thick coal-bearing fluviodeltaic-lacustrine succession (Lower to Middle Miocene, Upper Karpatian?/Lower Badenian) which is overlain by a 1,000-m-thick alluvio-deltaic conglomeratic succession (Apfelberg Formation, ?Middle/Upper Badenian) in the south. A three-stage model for the basin evolution has been reconstructed from structural analysis and basin fill geometries. During a first pull-apart phase, subsidence occurred along ENE-trending, sinistral strike-slip faults of the Mur-Mürz fault system and NE-SW to N-S-trending normal faults, forming a composite pull-apart basin between overstepping en-echelon strike-slip faults. The Seckau and Fohnsdorf sub-basins are considered as two adjacent pull-aparts which merged into one basin. During the second phase, N-S to NNW-SSE extension and normal faulting along the southern basin margin fault formed a half-graben, filled by wedge-shaped alluvial strata (Apfelberg Formation). During the third phase, after the end of basin sedimentation, the dextral Pöls-Lavanttal fault system reshaped the western basin margin into a positive flower structure.     

Self-sedimentation of phytoplankton blooms in the geologic record

Understanding the formation of laminated, organic-rich sediments is an essential topic for researchers interested in fossil fuels, biogeochemical cycles, Earth's environmental history and global change. Biologists have very recently demonstrated that some marine phytoplankton blooms actively govern their own sedimentation by the formation of sticky transparent gels that facilitate rapid aggregation, accelerated sinking and efficient export flux. Here we present fossil evidence of unfragmented, low-diversity phytoplankton assemblages preserved as sedimentary laminae and irregular flocs that are attributable to a similar phytoplankton-driven sedimentary mechanism we term ‘self-sedimentation’. The geological evidence suggests that self-sedimentation precludes significant heterotrophic grazing, propels the formation of some conspicuous hemipelagic sedimentary laminae and results in efficient carbon and opal flux to the sediments. We suggest that the self-sedimentation phenomenon may have broad implications for the geological history of biogeochemical cycling, oceanic ecological dynamics, and abrupt atmospheric/environmental change. Broader recognition of the self-sedimentation phenomenon as explicitly defined here is a prerequisite to testing these unconventional hypotheses.     

Crooked line, rough topography: advancing towards the correct seismic image

Seismic exploration in mountainous areas imposes serious compromises on both acquisition and processing. Access restrictions usually result in profiles that are not straight and are not recorded along the true dip direction (if there is a true dip direction!). Processing constraints often result in very poor approximate corrections for elevations and for deviations from a straight line. Most fundamentally, 2D acquisition and processing assumes that the earth is 2D; this assumption is often seriously violated in mountainous areas. While we cannot efficiently correct 2D seismic data for the effects of a fully 3D subsurface, we can improve the data quality in thrust areas where the assumption of 2D subsurface variation is reasonable. We do this in a series of small steps, which improves the accuracy of several approximations made in processing 2D land data.     

Geologische Vorgänge in den Alpen ab Obereozän im Spiegel vor allem der deutschen Molasse

Zusammenfassung Die vorquartäre Geschichte des Molassebeckens nördlich der Alpen läßt sich in 3 Großabschnitte unterteilen, in deren Ablauf sich umrißhaft die jeweils zugehörigen Entwicklungsstadien des aufsteigenden Gebirges widerspiegeln, die bisweilen umgekehrt auch von Ereignissen im Vorland beeinflußt werden. Der 1. Abschnitt (Obereozän bis Aquitan/ Ober-Eger) ist von der in den Westalpen beginnenden Hebung sowie von Bewegungen der savischen Dislokationsphase geprägt, in besonderem Maße ferner an der Rupel/ChattGrenze von der größten Meeresspiegelsenkung seit dem Kambrium. Im 2. Abschnitt (Burdigal/Eggenburg bis Unterpannon) verlagert sich die Hebungsaktivität zu den Ostalpen, womit im Vorland die große, E-W gerichtete Flußschüttung der Oberen Süßwassermolasse ausgelöst wird. In ihr verursacht die gewaltige Erderschütterung des Riesmeteoriten-Einschlags im höheren Baden vermutlich die Flußverlegung der Enns, eines ihrer beiden Hauptzubringer, zum Grazer Becken und damit eine sich u. a. im Schwermineralbestand (als A-Grenze) abzeichnende Änderung der Materialzufuhr aus dem Gebirge. Im 3. Abschnitt (Unterpannon bis Pliozän) geht infolge weiteren Aufsteigens der Alpen samt Vorland bei gleichzeitiger Verlagerung des Hebungszentrums wieder zur Westschweiz die bisherige Akkumulation in Denudation über, die von dem sich nun von Niederösterreich aus ins Molassebecken hineinfressenden Donausystem besorgt wird.Die während des 2. Großabschnitts von der Auflast der vorrückenden kalkalpinen Dekken aus ihrem Ablagerungsraum herausgequetschte ältere Molasse ist zu den alpenparallelen Mulden des gefalteten Bereichs zusammengeschoben, mit einer wohl erst im 3. Abschnitt entstandenen Achsendepression zwischen Iller und Mangfall. In diesen Zeitraum vor allem fällt auch die Verformung der jüngeren ungefalteten Molasse zu einer alpenparallelen Großmulde, deren Achse nach SW und E aushebt.

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The pre-Quaternary history of the Molasse basin north of the Alps can be subdivided into three major phases, in the course of which the respective associated evolutional stages of the rising mountains are reflected in outline. On the other hand, these stages are occasionally also influenced by events in the foreland. The first phase (Upper Eocene to Aquitanian/Upper Egerian) ist characterized by the uplifting beginning in the Western Alps and movements of the Savic dislocation phase, and in particular also at the Rupelian/Chattian boundary by the greatest eustatic lowering of the sea level since the Cambrian period. During the second phase (Burdigalian/Eggenburgian to Lower Pannonian) the uplifting shifts to the Eastern Alps, bringing about in the foreland the large E-W directed fluvial accretion of the Upper Fresh-water-Molasse. During its progress the enormous earth-tremor of the Ries meteoric impact in the upper Badenian presumably leads to the diversion of the Enns river, being one of the two main tributaries, to the Graz basin, resulting in a change in the material supply from the mountains, which is reflected in the heavy mineral content (designated as A-boundary). In the third phase (Lower Pannonian to Pliocene) the previous accumulation, as a result of the continuing uplifting of the Alps and the foreland with simultaneous shifting of the uplift centre back to Western Switzerland, turns to denudation which is effected by the Danube system extending from Lower Austria into the Molasse basin.The older Molasse squeezed out of its deposition area by the overburden of the advancing Austroalpine nappes has been compressed to the throughs of the folded zone along the Alps, with an axis depression between the rivers Iller and Mangfall, which has presumably not developed until the third phase. Above all, during this period the deformation of the younger unfolded Molasse to a large trough paralleling the Alps also took place; its axis rises to the SW and E.

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Résumé L'histoire préquaternaire du bassin molassique au nord des Alpes peut se diviser en trois périodes principales dont le déroulement reflète à grands traits les phases de développement corrélatives de la chaîne en voie de soulèvement. D'autre part, ces phases de développement sont de temps en temps influencées par des événements intervenus dans le bassin. La première période (Eocène supérieur à Aquitanien/Egerien supérieur) est marquée par le soulèvement commençant dans les Alpes occidentales, ainsi que par des mouvements de la phase de dislocation savique et, en particulier à la limite du Rupélien/Chattien, par le plus grand abaissement eustatique du niveau de la mer depuis le Cambrien. Pendant la seconde période (Burdigalien/Eggenburgien à Pannonien inférieur) l'activité de soulèvement se déplace vers les Alpes orientales, provoquant dans le bassin préalpin la grande accrétion fluviale de la Süßwassermolasse (Molasse d'eau douce) supérieure dirigée de l'est vers l'ouest. Le violent ébranlement terrestre produit dans celle-ci par l'impact de la météorite dans le Ries pendant le Badénien supérieur mène probablement le détournement de l'Enns, l'un des deux fleuves tributaires principaux, vers le bassin de Graz, donnant lieu à un changement dans le transport de matériaux venant des montagnes, ce qui se reflète dans la teneur en minerais lourds (dénommé « limite A »). Pendant la troisième période (Pannonien inférieur à Pliocène), l'accumulation antérieure, par suite du soulèvement continu des Alpes et du bassin préalpin, accompagné de la retraite du centre du soulèvement vers la Suisse occidentale, tourne à la dénudation qui est effectuée par le système danubien s'étendant dès lors de la Basse-Autriche au bassin molassique.La Molasse plus ancienne expulsée pendant la seconde période principale de son milieu de sedimentation par la pression des nappes austroalpines susjacentes en progression a été comprimée en auges de la zone pliée le long des Alpes, avec un abaissement axial entre l'Iller et le Mangfall, qui ne s'est probablement formé que dans la troisième période. Dans cette période surtout intervient la déformation de la Molasse plus récente non plissée qui prend la forme d'une grande auge parallèle aux Alpes, dont l'axe s'élève vers le sud-ouest et l'est.

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Herrn Dr. Dr. h. c. Artur Roll (Tübingen) gewidmet

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Nach einem Vortrag auf der 73. Jahrestagung der Geologischen Vereinigung in Berchtesgaden am 25. Februar 1983.