Strategien und Technologien einer pluralistischen Fern- und Nahwärmeversorgung in einem liberalisierten Energiemarkt unter besonderer Berücksichtigung der Kraft-Wärme-Kopplung und erneuerbarer Energien : Kurzfassung der Studie

Die Zusammenfassung dient zwei Zielen: Zunächst werden die wesentlichen Ergebnisse der Langfassung der o.g. Studie referiert; auf dieser Basis werden dann mögliche Maßnahmen und Strategien diskutiert, die kurzfristig (2000-2001) ergriffen werden könnten. Als Akteure kommen hierbei nicht nur die Bundesregierung, die wichtige Rahmenbedingungen zum Marktgeschehen wird setzen müssen, in den Fokus, sondern auch die Betreiber von Heizkraftwerken und KWK-Anlagen und deren Verbände, aber auch andere Akteure wie z. B. Contracting-Unternehmen und Forschungseinrichtungen. Da die Übergangsphase der Liberalisierung der europäischen Stromwirtschaft in den Jahren 2000-2005 eine besondere Herausforderung für die KWK-Entwicklung darstellt, wird auch ein kurzfristig wirksames Maßnahmenbündel zur Diskussion gestellt. Dem Leser sei zum Verständnis in Erinnerung gerufen, dass diese vorgelegte Analyse im Rahmen einer Vorstudie durchgeführt wurde und langfristig abgesicherte Aussagen auch Analysen mit einschließen müssten, die bis 2010 und 2020 reichen. Weiterführende Arbeiten sollen in einer geplanten Hauptstudie erfolgen

A high-quality annually laminated sequence from Lake Belau, Northern Germany: Revised chronology and its implications for palynological and tephrochronological studies

The annually laminated record of Lake Belau offers an exceptional opportunity to investigate with high temporal resolution Holocene environmental change, aspects of climate history and human impact on the landscape. A new chronology based on varve counts, 14C-datings and heavy metal history has been established, covering the last 9400 years. Based on multiple varve counting on two core sequences, the easily countable laminated section spans about 7850 varve years (modelled age range c. 9430 to 1630 cal. BP). Not all of the record is of the same quality but approximately 69% of the varves sequence is classified to be of high quality and only c. 5% of low quality. The new chronology suggests dates generally c. 260 years older than previously assumed for the laminated section of the record. The implications for the vegetation and land-use history of the region as well as revised datings for pollen stratigraphical events are discussed. Tephra analysis allowed the identification of several cryptotephra layers. New dates for volcanic eruptions are presented for the Lairg B event (c. 6848 cal. BP, 2s range 6930–6713 cal. BP), the Hekla 4 event (c. 4396 cal. BP, 2s range 4417–4266 cal. BP), and Hekla 3 eruption (c. 3095 cal. BP, 2s range 3120–3068 cal. BP)

Insights into mantle composition and mantle melting beneath mid-ocean ridges from postspreading volcanism on the fossil Galapagos Rise

New major and trace element and Sr, Nd, and Pb isotope data, together with 39Ar-40Ar ages for lavas from the extinct Galapagos Rise spreading center in the eastern Pacific reveal the evolution in magma compositions erupted during slowdown and after the end of active spreading at a mid-ocean ridge. Lavas erupted at 9.2 Ma, immediately prior to the end of spreading are incompatible element depleted mid-ocean ridge tholeiitic basalts, whereas progressively younger (7.5 to 5.7 Ma) postspreading lavas are increasingly alkalic, have higher concentrations of incompatible elements, higher La/Yb, K/Ti, 87Sr/86Sr, and lower 143Nd/144Nd ratios and were produced by smaller degrees of mantle melting. The large, correlated variations in trace element and isotope compositions can only be explained by melting of heterogenous mantle, in which incompatible trace element enriched lithologies preferentially contribute to smaller degree mantle melts. The effects of variable degrees of melting of heterogeneous mantle on lava compositions must be taken into account when using mid-ocean ridge basalt (MORB) to infer the conditions of melting beneath active spreading ridges. For example, the stronger “garnet signature” inferred from Sm/Nd and 143Nd/144Nd ratios for postspreading lavas from the Galapagos Rise results from a larger contribution from enriched lithologies with high La/Yb and Sm/Yb, rather than from a greater proportion of melting in the stability field of garnet peridotite. Correlations between ridge depth and Sm/Yb and fractionation-corrected Na concentrations in MORB worldwide could result from variations in mantle fertility and/or variations in the average degree of melting, rather than from large variations in mantle temperature. If more fertile mantle lithologies are preferentially melted beneath active spreading ridges, then the upper mantle may be significantly more “depleted” than is generally inferred from the compositions of MORB

Age and origin of Researcher Ridge and an explanation for the 14° N anomaly on the Mid-Atlantic Ridge by plume-ridge interaction

Highlights: • Researcher Ridge, a chain of volcanic seamounts in the central Atlantic is identified as a classical hotspot track; • The underlying small mantle plume is believed to get captured by the westward migrating Mid-Atlantic Ridge; • The bathymetric/geochemical anomaly of the Mid-Atlantic-Ridge at 14° N can therefore be explained by plume-ridge interaction. Abstract: Researcher Ridge is a 400 km long, WNW-ESE oriented chain of volcanic structures, located on ~20 to 40 Ma old oceanic crust on the western flank of the Mid-Atlantic Ridge (MAR) at ~15° N. Researcher Ridge has been little studied, and its age and origin are currently unclear. At roughly the same latitude (14–15° N), the MAR axis is bathymetrically elevated and geochemically enriched (hereafter referred to as the 14° N MAR anomaly). This study presents 40Ar/39Ar age data, major and trace elements, and Sr-Nd-Pb-Hf isotopic compositions of volcanic rocks dredged from several seamounts of the Researcher Ridge. In addition, new geochemical data of MORBs from two 13–14° N dredge sites on the MAR are also presented. The results reveal that Researcher Ridge lavas have geochemically enriched ocean island basalt compositions (chondrite-normalized [La/Sm]N = 1.7–5.0, and [Ce/Yb]N = 1.58–11.3) with isotopic signatures (143Nd/144Nd = 0.51294–0.51316, 87Sr/86Sr = 0.70266–0.70405, 206Pb/204Pb = 19.14–19.93, 207Pb/204Pb = 15.57–15.63, 208Pb/204Pb = 38.82–39.17, and 176Hf/177Hf = 0.28307–0.28312) trending towards the FOZO or HIMU mantle end member composition. Based on the new age and geochemical data, Researcher Ridge is interpreted as a classic hotspot track, albeit formed by a relatively weak melting anomaly. The lavas from the 14° N MAR anomaly have an enriched E-MORB type composition ([La/Sm]N = 1.81–2.29, [Ce/Yb]N = 1.6–3.9). Their isotopic compositions (143Nd/144Nd = 0.51298–0.51313, 87Sr/86Sr = 0.70250–0.70282, 206Pb/204Pb = 18.90–19.31, 207Pb/204Pb = 15.52–15.58, 208Pb/204Pb = 38.45–38.95, 176Hf/177Hf = 0.28315–0.28320) plot at the enriched end of the local MORB array and partly overlap the Researcher Ridge lava compositions, suggesting a genetic relationship. We propose that the 14° N MAR anomaly is caused by deflection of upwelling Researcher Ridge plume material towards the westward migrating MAR, causing the production of E-MORBs with similar isotopic compositions to the Researcher Ridge lavas. Once the plume was captured by the spreading ridge, off-axis hotspot track volcanism ceased, resulting in a seamount gap between the eastern end of the Researcher Ridge and the 14° N MAR anomaly