Multi-proxy analyses of sediment cores from the Pakistan continental margin

Late Holocene laminated sediments from a core transect centred in the oxygen minimum zone (OMZ) impinging at the continental slope off Pakistan indicate stable oxygen minimum conditions for the past 7000 calendar years. High SW-monsoon-controlled biological productivity and enhanced organic matter preservation during this period is reflected in high contents of total organic carbon (TOC) and redox-sensitive elements (Ni, V), as well as by a low-diversity, high-abundance benthic foraminiferal Buliminacea association and high abundance of the planktonic species Globigerina bulloides indicative of upwelling conditions. Surface-water productivity was strongest during SW monsoon maxima. Stable OMZ conditions (reflected by laminated sediments) were found also during warm interstadial events (Preboreal, Bølling-Allerød, and Dansgaard-Oeschger events), as well as during peak glacial times (17-22.5 ka, all ages in calendar years). Sediment mass accumulation rates were at a maximum during the Preboreal and Younger Dryas periods due to strong riverine input and mobilisation of fine-grained sediment coinciding with rapid deglacial sea-level rise, whereas eolian input generally decreased from glacial to interglacial times. In contrast, the occurrence of bioturbated intervals from 7 to 10.5 ka (early Holocene), in the Younger Dryas (11.7-13 ka), from 15 to 17 ka (Heinrich event 1) and from 22.5 to 25 ka (Heinrich event 2) suggests completely different conditions of oxygen-rich bottom waters, extremely low mass and organic carbon accumulation rates, a high-diversity benthic fauna, all indicating lowered surface-water productivity. During these intervals the OMZ was very poorly developed or absent and a sharp fall of the aragonite compensation depth favoured the preservation of pteropods. The abundance of lithogenic proxies suggests aridity and wind transport by northwesterly or northeasterly winds during these periods coinciding with the North Atlantic Heinrich events and dust peaks in the Tibetan Loess records. The correlation of the monsoon-driven OMZ variability in the Arabian Sea with the rapid climatic fluctuations in the high northern latitudes suggests a close coupling between the climates of the high and low latitudes at a global scale.

Documentation, profile descriptions and analytical results of loes profiles from Bavaria, southern Germany

This study investigates the landscape evolution and soil development in the loess area near Regensburg between approximately 6000-2000 yr BP (radiocarbon years), Eastern Bavaria. The focus is on the question how man and climate influenced landscape evolution and what their relative significance was. The theoretical background concerning the factors that controlled prehistoric soil erosion in Middle Europe is summarized with respect to rainfall intensity and distribution, pedogenesis, Pleistocene relief, and prehistoric farming. Colluvial deposits , flood loams, and soils were studied at ten different and representative sites that served as archives of their respective palaeoenvironments. Geomorphological, sedimentological, and pedological methods were applied. According to the findings presented here, there was a high asynchronity of landscape evolution in the investigation area, which was due to prehistoric land-use patterns. Prehistoric land use and settlement caused highly difIerenciated phases of morphodynamic activity and stability in time and space. These are documented at the single catenas ofeach site. In general, Pleistocene relief was substantially lowered. At the same time smaller landforms such as dells and minor asymmetric valleys filled up and strongly transformed. However, there were short phases at many sites, forming short lived linear erosion features ('Runsen'), resulting from exceptional rainfalls. These forms are results of single events without showing regional trends. Generally, the onset of the sedimentation of colluvial deposits took place much earlier (usually 3500 yr BP (radiocarbon) and younger) than the formation of flood loams. Thus, the deposition of flood loams in the Kleine Laaber river valley started mainly as a consequence of iron age farming only at around 2500 yr BP (radiocarbon). A cascade system explains the different ages of colluvial deposits and flood loams: as a result of prehistoric land use, dells and other minor Pleistocene landforms were filled with colluvial sediments. After the filling of these primary sediment traps , eroded material was transported into flood plains, thus forming flood loams. But at the moment we cannot quantify the extent ofprehistoric soil erosion in the investigation area. The three factors that controlled the prehistoric Iandscapc evolution in the Ioess area near Regensburg are as follows: 1. The transformation from a natural to a prehistoric cultural landscape was the most important factor: A landscape with stable relief was changed into a highly morphodynamic one with soil erosion as the dominant process of this change. 2. The sediment traps of the pre-anthropogenic relief determined where the material originated from soil erosion was deposited: either sedimentation took place on the slopes or the filled sediment traps of the slopes rendered flood loam formation possible. Climatic influence of any importance can only be documented as the result of land use in connection with singular and/or statistic events of heavy rainfalls. Without human impact, no significant change in the Holocene landscape would have been possible.

Geologic-hydrologic setting and surface sedimentology in the Persian Gulf

1. Morphology and sedimentation The deepest parts of the Persian Gulf lie off the Iranian coast. Several swells separate the Persian Gulf into the Western Basin, the Central Basin and the Strait of Hormuz, which leads without noticeable morphological interruption onto the Biaban Shelf; the latter gradually drops off towards the continental slope, which itself has a strongly subdivided morphology. The sediment distribution in the Western Basin runs parallel to the basin's axis to a depth of 50 -60 m. This is caused by the shallow and uniform slope of the Iranian coast into the Western Basin, by clear exposure of the area to the Shamal-Winds and by tidal currents parallel to the basin's axis. Most other parameters also show isolines parallel to the coast line. Data from the sediment analyses show a net transport which extends out along the Central Swell: coarse fraction > 63 µ, total carbonate content, carbonate in fine fractions < 2 µ, 2-6 µ and 20-63 µ, calcite-aragonite ratios in the fine fractions 2-6 µ and 20-63 µ and quartz-dolomite ratios in fine fraction 2-6 µ. At least the uppermost 10-40 m of this sediment is late Holocene. This implies sedimentation rates of several meters per 1000 years. The slope from the Iranian coast into the Central Basin (max. depth 100 m) is generally steeper, with interspersed islands and flats. Both facts tend to disturb a sediment dustribition parallel to the basin's axis over extensive areas and may preclude any such trend from being detected by the methods and sample net used. The spatial distribution of the coarse fraction, however, seems to indicate sediment transport at greater water depths perpendicular to the basin's long axis and along the steepest gradients well into the Central Basin. The flats of the Central Basin have a sediment cover distinctly different from those of the deeper basin areas. Characteristic parameters are the extremely high percentages of coarse grained sediments, total content of carbonate CO2 over 40, low total organic carbon content, (however values are high if calculated on the basis of the < 63 µ fraction), low total N-content, and low C/N ratios. These characteristics probably result from the absence of any terrigenous material being brought in as well as from exposure to wave action. Finest terrigenous material is deposited in the innermost protected part of the Hormuz Bay. In the deep channel cut into the Biaban Shelf which carries the Persian Gulf out-flow water to the Indian Ocean, no fine grained sediment is deposited as shown by grain size data. 2. Geographic settings and sedimentation Flat lands border the Arabian coast of the Persian Gulf except for the Oman region. The high and steep Zagros Mountains form the Iranian coastline. Flat topography in combination with generally low precipitation precludes fluviatile sediment being added from the South. Inorganic and biogenic carbonates accumulating under low sedimentation rates are dominant on the shallow Arabic Shelf and the slopes into the Western and Central Basins. The fluviatile sediment brought in from the Iranian side, however decisively determine the composition of the Holocene sediment cover in the Persian Gulf and on the Biaban Shelf. Holocene sediments extend 20-30 km seaward into the Western Basin and about 25 km on to the Biaban Shelf. As mentioned before, sedimentation rates are of several meters/1000 years. The rocks exposed in the hinterland influence the sediments. According to our data the Redbeds of the Zagros Mountains determine the colour of the very fine grained sediments near the Iranian Coast of the Persian Gulf. To the West of Hormuz, addition of carbonate minerals is particularly high. Dolomite and protodolomite, deposited only in this area, as well as palygorskite, have proven to be excellent trace minerals. To the East of Hormuz, the supply of terrigenous carbonates is considerably lower. Clay minerals appear to bring in inorganically bound nitrogen thus lowering the C/N ratio in these sediments especially off river mouths. 3. Climate and sedimentation The Persian Gulf is located in a climatically arid region. This directly affects sedimentation through increased wind action and the infrequent but heavy rainfalls which cause flash floods. Such flash floods could be responsible for transporting sedheats into the Central Basin in a direction perpendicular to the Gulf's axis. Eolian influx is difficult to asses from our data; however, it probably is of minor importance from the Iranian side and may add, at the most, a few centimeters of fine sediment per 1000 years. 4. Hydrology and sedimentation High water temperatures favor inorganic carbonate precipitation in southern margin of the Gulf, and probably on the flats, as well as biogenic carbonate production in general. High evaporation plus low water inflow through rivers and precipitation cause a circulation pattern that is typical for epicontinental seas within the arid climate region. Surface water flows in from the adjoining ocean, in this case the Indian Ocean and sinks to the bottom of the Persian Gulf mainly in the northern part of the Western Basin, on the "Mesopotamischer Flachschelf" ard probably in the area of the "Arabischer Flachschelf". This sinking water continually rejuvenates the bottom out-flow water. The inflowing surface water from the Indian Ocean brings organic matter into the Persian Gulf, additional nutrients are added by the "fresh" upwelling waters of the Gulf of Oman. Both nutrients and organic matter diminish very rapidly as the water moves into the Persian Gulf. This depletion of nutrients and organic matter is the reasonfor generally low organic carbon contents of the Persian Gulf sediments. The Central Swell represents a distinct boundary, to the west of which the organic carbon content are lower than to the east when sediment samples of similar grain size distribution are compared. The outflow carries well oxygenated water over the bottom of the Persian Gulf and the resulting oxidation further decreases the content of organic matter. In the Masandam-Channel and in the Biaban-Shelf channel, the outflowing water prevents deposition of fine material and transports sediment particles well beyond the shelf margin. The outflowing water remains at a depth of 200-300 m depending on its density and releases ist suspending sediment load to the ocean floor, irrespectative of the bottom morphology. This is reflected in several parameters in which the sediments from beneath the outflow differ from nearby sediments not affected by the outflowing water. High carbonate content of total samples and of the individual size fraction as well as high aragonite and dolomite contents of individual size fractions characterize the sediment beneath the outflowing water. The tidal currents, which avt more or less parallel to the Gulf's axis, favor mixing of the water masses, they rework sediments at velocities reported here. This fact enlarges to a certain degree the extent of our interfaces which are based on only a few sample points (Persian Gulf and Biaban Shelf one sample per 620 km**2, continental slope one sample per 1000 km**2). The water on the continental slope shows and oxygen minimum at 200-1200 m which favors preservation of organically-bound carbon in the sediment. The low pH-values may even permit dissolution of carbonate minerals.

Stress tests of ODP Site 131-808 sediments

Sediments undergoing accretion in trench-forearc systems are subjected to conditions of large lateral thrusting. This stress regime controls the mechanism of faulting as well as the yield and strength properties of the sediment. Understanding them is therefore crucial for the construction of quantitative models of sediment dynamics in convergent margin settings. For this purpose triaxial and oedometer tests were performed on six whole-round core samples recovered from Site 808 from depths between 173 and 705 mbsf. Samples from five depth intervals were subjected to a triaxial test program that was primarily designed to define yield and strength behavior. Test specimens were cut parallel and normal to the core axis. Additional five oedometer tests with similarly prepared specimens were performed on samples from four depth intervals to evaluate the directional state and degree of sediment compaction. Test results show that the degree of sediment compaction is higher than expected from overburden. This overcompaction increases with depth. A well-developed mechanical anisotropy is evident in all samples tested, regardless of their depth and lithology. Values of yield limit, stiffness, and shear strength are up to 40% higher in the horizontal direction compared to the vertical direction. In addition the test data demonstrate that the axis of the volumetric yield loci have rotated into extensional stress field. This verifies that the mechanical state of sediment in the accretionary wedge is controlled by in-situ stress conditions of extensional nature. The coefficients of lateral stress inferred suggest that the extensional stress regime becomes increasingly effective with depth.

Mineralogical-sedimentological and chemical investigation of sediments from Cross Bank off Florida

The sediments of a core of.1.55 m length taken on the windward side of the Cross Bank, Florida Bay, are clearly subdivided into two portions, as shown by grain size analysis: silt-sized particles predominate in the relatively homogeneous lower two thirds of the core. This is succeeded abruptly by a thin layer of sand, containing fragments of Halimeda. They indicate a catastrophic event in the Florida Bay region, because Halimeda does not grow within Florida Bay. Above this layer, the amount of sand decreases at first and then continuously increases right to the present sediment-water-interface. The median and skewness increase simultaneously with the increase in the sand and granule portion. We assume that the changing grain size distribution was determined chiefly by the density of the marine flora: during the deposition of the lower two thirds of the core a dense grass cover acted as a sediment catcher for the fine-grained detritus washed out of the shallow basins of the Florida Bay, and simultaneously prohibited renewed reworking. Similar processes go on today on the surface of most mud banks of Florida Bay. The catastrophic event indicated by the sand layer probably changed the morphology of the bank to such an extent that the sampling point was shifted more to the windward side of the bank. This side is characterized by less dense plant growth. Therefore, less detritus could be caught and the material deposited could be reworked. The pronounced increase in skewness in the upper third of the core certainly indicates a strong washing out of the smaller-sized particles. The sediments are predominantly made up of carbonates, averagely 88.14 percent. The average CaCO3-content is 83.87 percent and the average MgCO3-content amounts to 4.27 percent. The chief carbonate mineral is aragonite making up 60.1 percent of the carbonate portion in the average, followed by high-magnesian calcite (33.8 percent) and calcite (6.1 percent). With increasing grain size the aragonite clearly increases at the cost of high-magnesian calcite in the upper third of the core. Chemically, this is shown by an increase of the CaCO3 : MgCO3-ratio. This increase is mainly caused by the more common occurrence of aragonitic fragments of mollusks in the coarse grain fractions. The bulk of the carbonates is made up of mollusks, foraminifera, ostracods, and - to a much lesser extent - of corals, worm-tubes, coccolithophorids, and calcareous algae, as shown by microscopic investigations. The total amount of the carbonate in the sediments is biogenic detritus with the possible exception of a very small amount of aragonite needles in the clay and fine silt fraction. The individual carbonate components of the gravel and sand fraction can be relatively easy identified as members of a particular animal or plant group. This becomes very difficult in the silt and clay fraction. Brownish aggregates are very common in the coarse and medium silt fraction. It was not always possible to clarify their origin (biogenic detritus, faecal pellets or carbonate particles cemented by carbonates or organic slime, etc.). Organic matter (plant fragments, rootlets), quartz, opal (siliceous sponge needles), and feldspar also occur in the sediments, besides carbonates. The lowermost part of the core has an age of 1365 +/- 90 years, as shown by 14C analysis.

Sedimentology on profile Co1202 from Lake Ohrid

Lake Ohrid is probably of Pliocene age, and the oldest extant lake in Europe. In this study climatic and environmental changes during the last glacial-interglacial cycle are reconstructed using lithological, sedimentological, geochemical and physical proxy analysis of a 15-m-long sediment succession from Lake Ohrid. A chronological framework is derived from tephrochronology and radiocarbon dating, which yields a basal age of ca. 136 ka. The succession is not continuous, however, with a hiatus between ca. 97.6 and 81.7 ka. Sediment accumulation in course of the last climatic cycle is controlled by the complex interaction of a variety of climate-controlled parameters and their impact on catchment dynamics, limnology, and hydrology of the lake. Warm interglacial and cold glacial climate conditions can be clearly distinguished from organic matter, calcite, clastic detritus and lithostratigraphic data. During interglacial periods, short-term fluctuations are recorded by abrupt variations in organic matter and calcite content, indicating climatically-induced changes in lake productivity and hydrology. During glacial periods, high variability in the contents of coarse silt to fine sand sized clastic matter is probably a function of climatically-induced changes in catchment dynamics and wind activity. In some instances tephra layers provide potential stratigraphic markers for short-lived climate perturbations. Given their widespread distribution in sites across the region, tephra analysis has the potential to provide insight into variation in the impact of climate and environmental change across the Mediterranean.

Mineralogy and petrology of Black Sea Basin sediments

The origin and modes of transportation and deposition of inorganic sedimentary material of the Black Sea were studied in approximately 60 piston, gravity, and Kasten cores. The investigation showed that the sediment derived from the north and northwest (especially from the Danube) has a low calcite-dolomite ratio and a high quartz-feldspar ratio. Rock fragments are generally not abundant; garnet is the principal heavy mineral and illite is the predominant clay mineral. This sedimentary material differs markedly from that carried by Anatolian rivers, which is characterized by a high calcite-dolomite ratio and a low quartz-feldspar ratio. Rock fragments are abundant; pyroxene is the principal heavy mineral and montmorillonite is the predominant clay mineral. In generel, the clay fraction is large in all sediments (27.6-86.9 percent), and the lateral distributian indicates an increase in clay consent from the coasts toward two centers in the western and eastern Black Sea basin. Illite is the most common clay mineral in the Black Sea sediments. The lateral changes in composition of the clay mineral can easily be traced to the petrologic character of northern (rich in illite) and southern (rich in montmorillonite) source areas. In almost all cores, a rhythmic change of the montmorillonite-illite ratio with depth was observed. These changes may be related to the changing influence of the two provinces during the Holocene and late Pleistocene. Higher montmorillonite content seems to indicate climctic changes, probably stages of glaciation end permafrost in the northern area, at which time the illite supply was diminished to a large extent. The composition of the sand fraction is relatad to the different petrologic and morphologic characteristics of two major source provimces: (1) a northern province (rich in quartz, feldspars, and garnet) characterized by a low elevation, comprising the Danube basin area and the rivers draining the Russian platform; and (2) a southern province (rich in pyroxene and volcanic and metamorphic rocks) in the mountainous region of Anatolia and the Caucasus, characterized by small but extremely erosive rivers. The textural properties (graded bedding) of the deep-sea send layers clearly suggest deposition from turbidity currents. The carbonate content of the contemporary sediments ranges from 5 to 65 percent. It increases from the coast to a maximum in two centers in the western and eastern basin. This pattern reflects the distribution of the <2-µm fraction. The contemporary mud sedimentation is governed by two important factors: (1) the deposition of terrigenous allochthonous material of low carbonate content originating from the surrounding hinterland (northern and southern source areas), and (2) the autochthonous production of large quantities of biogenic calcite by coccolithophores during the last period of about 3,000-4,000 years.

Microflora from Molasse sediments in southern Germany

1. Polleninventar: Erstmals wurde der Sporomorpheninhalt der Süssbrackwassermolasse und der Oberen Süsswassermolasse Südbayerns einer umfassenden Sichtung unterzogen. Von den überprüften 92 Fundstellen erwiesen sich 55 als sporomorphenführend. Nur 15 davon waren so ergiebig, daß ihr Inhalt quantitativ erfaßt und als Grundlage für die Erstellung eines Diagramms herangezogen werden konnte. Dennoch weist der systematische Katalog 272 Formen auf. Dies ist eine im Vergleich mit anderen, in neuerer Zeit bearbeiteten neogenen Pollenfloren Mitteleuropas sehr große Zahl, wie folgende Angaben belegen: Niederrheinische Braunkohle 175 Arten, Braunkohle der Oberpfalz 138 Arten, subalpine Flözmolasse Bayerns 93 Arten und subalpine Molasse der Ostschweiz und der zentralen und westlichen Paratethys 219 Arten. Dieser Reichtum erklärt sich unschwer aus der Größe des Untersuchungsgebietes, das vom Allgäu im Westen bis an die Salzach im Osten reichte. Überwiegend gehören die nachgewiesenen Formen gutbekannten Arten bzw. Formenkreisen an. Deshalb wurde lediglich die Aufstellung von 2 neuen Gattungen, 19 neuen Arten sowie 5 Neukombinationen nötig. Neue Genera: Nr. (165) Ludwigiapollis Nr., (248) Caesalpiniaceaepollenites, 311 Neue Spezies: (039) Polypodiaceoisporltes subtriangularis, (046) P. pityogrammoides, (067) Perinomonoletes imperfectus, (124) Cycadopltes gemmatus, (125) C. concinus, (133) Lillacidites tener, (137) Nupharipollenites microechinatus, (150) Polyporopollenites nanus, (161) Porocolpopollenites subrotundus, (165) Ludwigiapollis labiatus, (169) Sporotrapoidites cucculatus, (190) Tricolpopollenites cribosus, (192) T. variabilis, (204) Tricolporopollenites pulcher, (210) T. operculiferus, (213) T. pseudomarcodurensis, (217) T. magnolaevigatus, (245) Umbelliferaepollenites achldorfensis, (248) Caesalpiniaceaepollenites antiquus Neukombinationen: (081) Pityosporites koraensis, (128) Magnoliaepollenites magnolioides, (130) M. graciliexinus, (168) Sporotrapoidites erdtmannii, (177) Chenopodipollis psilatoides. Für die meisten der vorgefundenen Sporomorphen sind die Lieferpflanzen bereits bekannt. Dennoch gingen parallel zur Bestimmung, d.h. der Zuordnung der Funde zu Gruppen des morphographischen Sporomorphensystems, die Bemühungen auch dahin, solche Lieferpflanzen, v.a. der selteneren oder neu gefundenen Sporomorphen, zu ermitteln; einige der neuen Arten sind in ihrer Verwandtschaft eindeutig, was durch die Benennung zum Ausdruck gebracht wird (s.o). Für die Mehrzahl der neuen Spezies und für viele bisher in ihrer Verwandtschaft unklare Formen ließ sich die botanische Deutung zumindest eingrenzen. Dies gelang für 148 Formen. Es handelt sich dabei teils um subtropisch-tropische Gewächse, teils aber auch um Pflanzen gemäßigter Klimata. Für genaue Zuweisungen sind jedoch umfangreiche Rezentvergleiche nötig, die einer eigenen Bearbeitung vorbehalten bleiben müssen. Auch einige als Sammelgruppen behandelte Formenkreise erfordern für eine Aufgliederung detailliertere Untersuchungen als sie in diesem Rahmen durchführbar waren. (z. B. Tricolpopollenites asper, T. sp. 2 u.a.). Andere Formen und Gattungen wiederum erwiesen sich dagegen als viel zahlreicher und leichter differenzierbar als bisher angenommen (z. B. Pinaceen, Magnoliaceen, Cyperaceen). In diesem Zusamenhang ist auch zu erwähnen, daß von Hemitrapa zwei Arten mit offensichtlich stratigraphischer Aussagekraft unterscheidbar sind; die Interpretation von Tricolporopol1enltes wackersdorfensis sensu MOHR & GREGOR (1984) als Gleditsia muß nach vorliegenden Erkenntnissen dagegen in Frage gestellt werden. Für 36 Formspezies blieb die Lieferpflanze völlig unbekannt oder es lassen sich höchstens vage Vermutungen anstellen. 2. Biostratigraphie: Fragen der Brauchbarkeit von Mikrofloren für die stratgraphische Gliederung der jüngsten Molassesedimente Südbayerns bildeten den zweiten Schwerpunkt vorliegender Bearbeitung. a) Reichweite: Die Fülle des gefundenen Sporomorphenmaterials brachte es mit sich, daß bei etlichen Formen eine weitere stratigraphische Reichweite als bisher angenommen festgestellt wurde. Zum Teil wurde diese Revision durch die Neugliederung des Paratethys-Miozäns nötig. b) Palynologische Gliederung: Im Laufe der Untersuchungen zeigte sich bald, daß allein auf der Basis der mikrofloristischen Bearbeitung kein von anderen Fossilresten unabhängiges stratigraphisches Gliederungsschema zu finden war. Weder die von anderen Autoren favoritisierte Leitformen-Methode, noch die Aufgliederung nach Klimaelementen ergab ein brauchbares Bild. Lediglich die bekannte generelle Abnahme der miozänen, paläotropischen und thermophilen Elemente und die Zunahme der pliozänen, arktoteriären und gemäßigten während des Neogens ließ sich deutlich ausmachen. Dagegen ermöglicht die Berücksichtigung des Sporomorpheninhalts eine Ergänzung und Deutung der vertebrat-stratigraphisch ausgeschiedenen Abfolgen. Voraussetzung ist die Möglichkeit einer Zuordnung zu einer natürlichen Art, Gattung oder wenigstens Familie und daraus ableitbar wiederum die Zuordnung zu einer oder mehreren Pflanzengesellschaften. Aufgeteilt nach Diversität, Dominanz und Verhältnis von 'Feuchtpflanzen' bzw. autochthonen Gemeinschaften zu mesophilen Phanerophyten bzw. allochthonen Gemeinschaften lassen sich in Südbayern fünf Pollenbilder erkennen, die mit den MN-Einheiten der Zoostratigraphie in Beziehung gebracht werden können. Die Pollenbilder 1 und 2, ungefähr entsprechend den Säugereinheiten 4b und 5, dokumentieren gattungsreiche, polydominante Mikrofloren, deren Lieferpflanzen vor allem verschiedenen Naß- und Feuchtgesellschaften angehören. Dementprechend sind Pteridaceen, Schizaeaceen, Cyperaceen und Poaceen relativ häufig. Das Pollenbild 1 (Langenau und Rauscheröd) zeichnet sich durch eine gewisse Artenarmut aus, wohingegen im Pollenbild 2 (Hitzhofen und Rittsteig) die Diversität zunimmt und Palmenpollen neben anderen mesophilen Akzessorien eine merkliche Rolle spielt. Bemerkenswert ist in den Entnahmeprofilen das Vorkommen kohliger Sedimente. Bezeichnend für Sporomorphenbild 3 sind oligodominante Mikrofloren, zusammengesetzt aus Elementen artenarmer Au- und Sumpfwälder (Taxodiaceen, Cyperaceen) sowie mesophiler 'Pionierwälder' (Pinaceen, Leguminosen). Fehlende Kohlebildung und das Zurücktreten mesophiler, d. h. allochthoner Lieferpflanzen sind weitere Charakteristika. Dieses Sporomorphenbild mit den Fundpunkten Gallenbach und Unterneul enspricht ungefähr der Säugereinheit MN 6. Die beiden stratigraphisch jüngsten Pollendiagramme 4 und 5 setzen sich deutlich von dem vorhergehenden ab. Belegt sind nun wiederum gattungsreiche, polydominante Pflanzenge seIl schaften feuchter, aber nicht nasser Biotope, in denen es ebenfalls mancherorts zur Kohlebildung kam. Gegenüber den Sporomorphenbildern und 2 ist der Anteil mesophiler Lieferpflanzen deutlich erhöht auf Kosten der Feuchtelemente. Letzteres gilt vor allem für das Sporomorphenbild 5 (Leonberg), in dem Fagaceen Pollen (Quercus, Fagus) vorherrscht. sporomorphenbild 4 entspricht annähernd MN 8 mit den Fundpunkten Hassenhausen und Achldorf, während Leonberg, nahe Marktl gelegen, MN 9 zugehört. Auf dem Umweg über diese an der Säugetierstratigraphie 'geeichten' Mikrofloren gelingt es, stratigraphisch unsichere Fundpunkte, wenn sie nur genügend formen- und individuenreich sind (Burtenbach, Lerchenberg, Wemding), einzuordnen. Auf diese Weise ergibt sich die in Diagramm 10 dargestellte Reihung vom Liegenden zum Hangenden. Dürftige Sporomorphenfloren oder Floren, die ausschließlich autochthone Feuchtelemente zeigen, können pollenstratigraphisch nicht sicher angesprochen werden, weil ihr Pollendiagramm undeutlich bleiben muß. Entsprechend der anerkannten Unterstellung, daß Phytostratigraphie zugleich Klimastratigraphie ist, läßt die dargestellte, im Grunde auf der Ausscheidung verschiedener Ukotypen basierende Gliederung sich auch paläoklimatisch interpretieren: Danach ist das verarmte Sporomorphenbild 3 in Südbayern als Ausdruck des vegetationsgeschichtlichen Pessimums anzusehen. Da die nachgewiesenen Sippen noch höhere Wärmeansprüche besitzen, ist nicht ein Temperaturrückgang, sondern ein Absinken der Niederschlagsmenge als begrenzender Faktor am wahrscheinlichsten und auf diese Weise das Ausbleiben von Pollen mesophiler Phanerophyten des Hinterlandes einleuchtend. 3. Paläogeographie: Bei dem Versuch, mit benachbarten Gebieten stratigraphische Beziehungen herzustellen, ergab sich, daß dies zwar über eine kürzere Entfernung recht gut gelingt, daß aber vor allem zu den Mikrofloren der niederrheinischen Braunkohle ein signifikanter Unterschied besteht: In Süddeutschland lassen die Pollendiagramme auf eine raschere Veränderung in der Zusammensetzung der Wälder schließen. Mit anderen Worten: altersgleiche Mikrofloren in Nordwestdeutschland täuschen ein höheres Alter vor. Erst im Obersarmat ähneln sich die jeweiligen Sporomorphenbilder. Damit erklärt sich auch, daß frühere Bearbeiter Schwierigkeiten hatten, mikrofloristische Befunde aus Süd- und Nordwestdeutschland miteinander zu korrelieren. Als Ursache für dieses überraschende Phänomen einer mittelmiozänen Diagrammverschiebung wird die stärkere, sprich länger andauernde maritime Beeinflussung des Niederrheingebietes angesehen.