Die Hochflächen-Treppe der Nordeifel und ihre Beziehungen zum Tertiär und Quartär der Niederrheinischen Bucht

The tableland of the northern Eifel consists of a whole series of levelling planations which descend like steps to the plain of the Lower Rhine or form broad terraces along the river valleys. A similar staircase structure can be seen in the Cretaceous range of the Aachener Wald. The oldest obliquely situated plateau of the Hohe Venn is a resurrected fossil peneplain which was formed before the Maastricht formation as can be proved by scanty remains of the flinty chalk (Maastricht) which still overlays this peneplain at the present time. Therefore the great elevation of the northern Eifel to heights of 2280 feet above sea-level did not follow until later than Upper Cretaceous.The indentation of this old Cretaceous peneplain presumably resulted in the formation of an older system of plateaus in Oligocene and in a system of young plateaus in Miocene which had the appearance of a staircase. These tableland systems originated in times of slight elevation in which superficial denudation must have predominated under the influence of a damp climate and intensive chemical decomposition of the rocks. During the Lower Miocene and Pliocene epochs considerable elevatory movements occurred which led occasionally to the formation of steep obsequent slopes at the edges of both systems. During the Lower Pleistocene epoch glacial conditions existed and at this time the main period of terrace formation occurred. In the course of this period there was a great gravel accumulation which was linked with lateral erosion and which, whith the aid of its valley terraces and rubble remains, can be traced as far as the foreland. A later, very marked incision of the rivers can be traced back to great elevations of land which occurred after this period. The rhythmic alternation of periods of elevation and inactivity can be seen in the morphological development of the northern Eifel. The individual periods of tableland and terrace formation can be related to corresponding sediments belonging to the Upper Tertiary and the Quaternary periods.

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Résumé Le paysage en plateaux emboîtés du Nord de l'Eifel se compose de toute une série de surfaces de nivellement qui descendent en gradins vers la plaine basse du Rhin inférieur ou constituent de larges terrasses le long des vallées fluviales. Une pareille structure en plateaux étagés est décelable dans la petite montagne crétacée du Aachener Wald. Le plus ancien haut plateau incliné des Hautes Fagnes représente une ancienne pénépleine à nouveau exhumée qui s'est formée avant le Maastrichtien comme on peut le démontrer par des restes peu abondants d'éluvions à silex (pierre à feu) qui lui servait autrefois de couverture. Le fort soulèvement du Nord de l'Eifel jusqu'à des hauteurs de 760 au dessus du niveau de la mer ne s'est produit par conséquent qu'après le crétacé supérieure.Á l'oligocène, un système plus ancien de surfaces applanies étagées et au miocène, un système de surfaces plus jeunes ont été probablement entaillés en gradins dans cette ancienne pénéplaine crétacée. Ces systèmes de plateaux emboîtés ont pris naissance à des époques de faible soulèvement, où l'érosion en surface a dû prédominer sous l'influence d'un climat humide et d'une décomposition chimique intensive de la roche. Au miocène inférieur et au pliocène ils ont chaque fois produit des mouvements de soulèvement assez forts qui ont entraîné la formation de versants à profil plus abrupt au bord des deux systèmes. Dans les conditions glaciaires, du pleistocène ancien, de l'époque des principales terrasses, il se produisit un important remblaiement de cailloutis uni à une érosion latérale et que l'on peut suivre jusque dans les parties avancées du territoire à l'aide de ses terrasses de vallées et de ses restes de cailloutis. Une forte entaille ultérieure des fleuves remonte à de vastes soulèvements de terrain postérieurs à cette époque. C'est ainsi que dans l'évolution morphologique du Nord de l'Eifel s'exprime l'alternance rythmique de périodes de soulèvement et de repos. Les différentes époques de formations de hauts plateaux étagés et de terrasses peuvent être mises en relation avec des sédiments correspondants parallèles du tertiaire supérieur et du quaternaire de la baie du Rhin inférieur.

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CO2 Mitigation by Agriculture: An Overview

Agriculture currently contributes significantly to the increase of CO2 in the atmosphere, primarily through the conversion of native ecosystems to agricultural uses in the tropics. Yet there are major opportunities for mitigation of CO2 and other greenhouse gas emissions through changes in the use and management of agricultural lands. Agricultural mitigation options can be broadly divided into two categories: (I) strategies to maintain and increase stocks of organic C in soils (and biomass), and (ii) reductions in fossil C consumption, including reduced emissions by the agricultural sector itself and through agricultural production of biofuels to substitute for fossil fuels.Reducing the conversion of new land to agriculture in the tropics could substantially reduce CO2 emissions, but this option faces several difficult issues including population increase, land tenure and other socio-political factors in developing countries. The most significant opportunities for reducing tropical land conversions are in the humid tropics and in tropical wetlands. An important linkage is to improve the productivity and sustainability of existing agricultural lands in these regions.Globally, we estimate potential agricultural CO2 mitigation through soil C sequestration to be 0.4-0.9 Pg C y-1, through better management of existing agricultural soils, restoration of degraded lands, permanent "set-asides" of surplus agricultural lands in temperate developed countries and restoration of 10-20% of former wetlands now being used for agriculture. However, soils have a finite capacity to store additional C and therefore any increases in C stocks following changes in management would be largely realized within 50-100 years.Mitigation potential through reducing direct agricultural emissions is modest, 0.01-0.05 Pg C y-1. However, the potential to offset fossil C consumption through the use of biofuels produced by agriculture is substantial, 0.5-1.6 Pg C y-1, mainly through the production of dedicated biofuel crops with a smaller contribution (0.2-0.3 Pg C y-1) from crop residues.Many agricultural mitigation options represent "win-win" situations, in that there are important side benefits, in addition to CO2 mitigation, that could be achieved, e.g. improved soil fertility with higher soil organic matter, protection of lands poorly suited for permanent agriculture, cost saving for fossil fuel inputs and diversification of agricultural production (e.g. biofuels). However, the needs for global food production and farmer/societal acceptability suggest that mitigation technologies should conform to: (I) the enhancement of agricultural production levels in parts of the world where food production and population demand are in delicate balance and (ii) the accrual of additional benefits to the farmer (e.g., reduced labor, reduced or more efficient use of inputs) and society at large.     

THE ADVERSE IMPACT OF HUMAN ACTIVITIES ON FLOOD CONTROL IN THE HUAIHE BASIN

LIN~DUCnONTheHuaiheBasinislOCatedbetWeen31"-36"llorthemlahtudeand112"-121"easternlongitude,andcoversatotalareaofabout269,000sq.kin,OfwhichthemountainousandhillyareasocCUPyl/3,theplainsandlow-iringland2/3.ThebasinelicitSsalientphysicalgeographicalfeatllTesasfollowsf(l)Thereisnoobviousmountaindividebe~ntheWatershedoftheriVerandtheYellowforerBasinaswellastheYangtZeRadBasin.MostofthetributariesinthenoalbudoftheHuaiheforertakethesouthdikesOftheYellowherasthedivide.(2)TheriVerbedofthetr…     

Impacts into quartz sand: Crater formation,shock metamorphism,and ejecta distribution in laboratory experiments and numerical models

We investigated the ejection mechanics by a complementary approach of cratering experiments, including the microscopic analysis of material sampled from these experiments, and 2‐D numerical modeling of vertical impacts. The study is based on cratering experiments in quartz sand targets performed at the NASA Ames Vertical Gun Range. In these experiments, the preimpact location in the target and the final position of ejecta was determined by using color‐coded sand and a catcher system for the ejecta. The results were compared with numerical simulations of the cratering and ejection process to validate the iSALE shock physics code. In turn the models provide further details on the ejection velocities and angles. We quantify the general assumption that ejecta thickness decreases with distance according to a power‐law and that the relative proportion of shocked material in the ejecta increase with distance. We distinguish three types of shock metamorphic particles (1) melt particles, (2) shock lithified aggregates, and (3) shock‐comminuted grains. The agreement between experiment and model was excellent, which provides confidence that the models can predict ejection angles, velocities, and the degree of shock loading of material expelled from a crater accurately if impact parameters such as impact velocity, impactor size, and gravity are varied beyond the experimental limitations. This study is relevant for a quantitative assessment of impact gardening on planetary surfaces and the evolution of regolith layers on atmosphereless bodies.     

Mining lakes as groundwater‐dominated hydrological systems: assessment of the water balance of Mining Lake Plessa 117 (Lusatia,Germany) using stable isotopes

In the present study, the stable isotopes δ¹⁸O and δ²H were used for assessment of the water balance in a heterogeneously structured catchment area in the Lusatian Lignite Mining District, in particular, for estimation of the annual groundwater inflow and outflow (I_GW and O_GW) of Mining Lake Plessa 117. The application of stable isotopes was possible since the water exchange in the catchment area had reached steady‐state conditions after the abandonment of mining activities in 1968 and the filling of the voids and aquifers by re‐rising groundwater in the years thereafter. Diverging slopes of the Evaporation Line and the Global Meteoric Water Line manifested as evaporation from the lake catchment area. The calculated isotope water balance was compared with the commonly used surface water balance, which is unable to differentiate between I_GW and O_GW, and with a local groundwater model. The groundwater model calculated an I_GW of about 811 000 m³ yr^?1 and an O_GW close to zero, whereas the isotope water balance showed fluxes of about 914 000 and 140 000 m³ yr^?1, respectively. Considering the contribution of the groundwater inflow to the total annual input into the lake (ΔI_T) and the mean residence time (τ), where the groundwater model and the isotope water balance calculated 42 and 47% for ΔI_T and 4·3 and 3·9 years for τ, respectively, it was shown that both water balance calculation methods led to comparable results despite the differences in I_GW and O_GW. Copyright © 2008 John Wiley & Sons, Ltd.     

Exact five-dimensional cosmological solutions

We derive some new perfect solutions in five dimensions. The solutions given are the generalizations of theL(4, 7) vacuum solution given recently by Demaret and Hanquin (1985) in an incorrect form only.     

Comment on the Guzmán-Bianchi type-VII h solutions

It is shown that the recently presented Brans-Dicke-Bianchi type-VII _h perfect fluid solutions by Guzmán (1989) are nothing but the solutions given already by us in our previous paper (Lorenz-Petzold, 1984).     

AMS radiocarbon dating and varve chronology of Lake Soppensee: 6000 to 12000 14C years BP

For the extension of the radiocarbon calibration curve beyond 10000 ¹⁴C y BP, laminated sediment from Lake Soppensee (central Switzerland) was dated. The radiocarbon time scale was obtained using accelerator mass spectrometry (AMS) dating of terrestrial macrofossils selected from the Soppensee sediment. Because of an unlaminated sediment section during the Younger Dryas (10000–11000 ¹⁴C y BP), the absolute time scale, based on counting annual layers (varves), had to be corrected for missing varves. The Soppensee radiocarbon-verve chronology covers the time period from 6000 to 12000 ¹⁴C y BP on the radiocarbon time scale and 7000 to 13000 calendar y BP on the absolute time scale. The good agreement with the tree ring curve in the interval from 7000 to 11450 cal y BP (cal y indicates calendar year) proves the annual character of the laminations. The ash layer of the Vasset/Killian Tephra (Massif Central, France) is dated at 8230±140 ¹⁴C y BP and 9407±44 cal y BP. The boundaries of the Younger Dryas biozone are placed at 10986±69 cal y BP (Younger Dryas/Preboreal) and 1212±86 cal y BP (Alleröd/Younger Dryas) on the absolute time scale. The absolute age of the Laacher See Tephra layer, dated with the radiocarbon method at 10 800 to 11200 ¹⁴C y BP, is estimated at 12350 ± 135 cal y BP. The oldest radiocarbon age of 14190±120 ¹⁴C y BP was obtained on macrofossils of pioneer vegetation which were found in the lowermost part of the sediment profile. For the late Glacial, the offset between the radiocarbon (10000–12000 ^14C y BP) and the absolute time scale (11400–13000 cal y BP) in the Soppensee chronology is not greater than 1000 years, which differs from the trend of the U/Th-radiocarbon curve derived from corals.     

A Pan-African alkaline pluton intruding the Saramuj Conglomerate,south-west Jordan

The geological setting, petrography and bulk mineral chemistry of a monzodiorite and a presumably consanguineous megaporphyry with large (up to 25 cm) labradorite megacrysts, both intruding the upper Proterozoic Saramuj Conglomerate in south-west Jordan (south eastern shore of the Dead Sea), were examined. The crystallization temperatures of the monzodiorite and the megaporphyry as determined from pyroxene thermometry and supported by contact metamorphic mineralogy are about 700 and 900°C, respectively. The intrusion depth of the monzodiorite is about 3–4 km. The monzodiorite was emplaced in the Saramuj Conglomerate at about 595 + 2 Ma ago according to Rb/Sr and U/Pb age determinations.The stratigraphic positions of the monzodiorite, megaporphyry and their host rock (the Saramuj Conglomerate) were compared with time-equivalent lithologies in the Arabian-Nubian Shield. Correspondence to: H. Wachendorf