A simplified hydrodynamic mesoscale model suitable for use over high plateau regions

Summary A simplified hydrodynamic primitive equation model in -coordinates is described. This model includes the main physical processes that influence development and motion of mesoscale vortices over plateau regions: elevated terrain effects, effects of large-scale and synoptic-scale systems on the mesoscale systems, sensible heating from the earth's surface, moisture cycle and condensation heating released by both large-scale stable precipitation and cumulus convective precipitation, evaporation and the feedback effect of precipitation on evaporation, friction in the planetary boundary layer, horizontal diffusion by subgrid scale eddies and vertical eddy flux of meteorological elements (momentum, temperature, moisture, etc.) due to turbulence, cumulus convection and other smaller-scale physical processes. The model incorporates observed data as much as possible and equations are simplified so that it may be run using either a high-speed computer or a desktop computer.Two developing vortices that originated over the Qinghai-Xizang (Tibet) Platau and moved eastward producing heavy precipitation over the lower elevations are used to test the model. It is shown that the model is capable of simulating the major features of the vortices including the precipitation distribution and may be used for studies of mesoscale and synoptic scale weather systems over plateau regions.

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Ein vereinfachtes für hochländer geeignetes hydrodynamisches mesoscale-modell

Zusammenfassung Es wird ein vereinfachtes hydrodynamisches Grundgleichungsmodell in -Koordinaten be schrieben. Dieses Modell beinhaltet die wichtigsten physikalischen Prozesse, die die Entwicklung und Bewegung von mesoskaligen Wirbeln über Hochplateaus beeinflussen: Effekte der Hochfläche, Effekte von großräumigen und synoptischen Systemen, die fühlbare Wärme von der Erdoberfläche, den Feuchtigkeitskreislauf und die Kondensationswärme, sowohl von großräumigen als auch von Konvektionsniederschlägen, die Evaporation und die Beeinflussung der Evaporation durch den Niederschlag, die Reibung in der planetaren Grenzschicht, die horizontale Diffusion durch Turbulenzen, die kleiner als die Gitterkonstante sind und den vertikalen Fluß meteorologischer Elemente (Impuls, Temperatur, Feuchte etc.) durch Turbulenzen, Konvektion und andere kleinräumige Prozesse. In das Modell sind die Beobachtungswerte weitestgehend integriert und die Gleichungen soweit vereinfacht, daß es sowohl auf einem Hochleistungs- als auch auf einem Mikrocomputer laufen kann.Zum Testen des Modells wurden zwei sich entwickelnde Wirbel verwendet, die vom Qinghai-Xizang-Plateu (Hochland von Tibet) ausgingen, sich ostwärts bewegten und dabei zu schweren Niederschlägen in den Tiefländern führten. Es wird gezeigt, daß das Modell die wichtigsten Eigenschaften der Wirbel und die Niederschlagsverteilung simulieren und für Untersuchungen von mesoskaligen und synoptischen Wettersystemen über Hochländern herangezogen werden kann.

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With 18 figures     

The Sudbury Structure (Ontario,Canada): a tectonically deformed multi-ring impact basin

The occurrence of shock metamorphic features substantiates an impact origin for the 1.85 Ga old Sudbury Structure, but this has not been universally accepted. Recent improvements in knowledge of large-scale impact processes, combined with new petrographic, geochemical, geophysical (LITHOPROBE) and structural data, allow the Sudbury Structure to be interpreted as a multi-ring impact structure. The structure consists of the following lithologies: Sudbury Breccia —dike breccias occurring up to 80 km from the Sudbury Igneous Complex (SIC); Footwall rocks and Footwall Breccia — brecciated, shocked crater floor materials, in part thermally metamorphosed by the overlying SIC; Sublayer and Offset Dikes, Main Mass of the SIC and Basal Member of the Onaping Formation (OF) — geochemically heterogeneous coherent impact melt complex ranging from inclusion-rich basal unit through a dominantly inclusion-free to a capping inclusion-rich impact melt rock; Grey Member of OF — melt-rich impact breccia (suevite); Green Member of OF — thin layer of fall back ejecta; Black Member of OF — reworked and redeposited breccia material; Onwatin and Chelmsford Formations — post-impact sediments. Observational and analytical data support an integrated step-by-step impact model for the genesis of these units. Analysis of the present spatial distribution of various impact-related lithologies and shock metamorphic effects result in an estimated original rim-to-rim diameter of the final crater of 200 or even 280 km for the Sudbury Structure, prior to tectonic thrusting and deformation during the Penokean orogeny.     

Experimental impact cratering: A summary of the major results of the MEMIN research unit

This paper reviews major findings of the Multidisciplinary Experimental and Modeling Impact Crater Research Network (MEMIN). MEMIN is a consortium, funded from 2009 till 2017 by the German Research Foundation, and is aimed at investigating impact cratering processes by experimental and modeling approaches. The vision of this network has been to comprehensively quantify impact processes by conducting a strictly controlled experimental campaign at the laboratory scale, together with a multidisciplinary analytical approach. Central to MEMIN has been the use of powerful two-stage light-gas accelerators capable of producing impact craters in the decimeter size range in solid rocks that allowed detailed spatial analyses of petrophysical, structural, and geochemical changes in target rocks and ejecta. In addition, explosive setups, membrane-driven diamond anvil cells, as well as laser irradiation and split Hopkinson pressure bar technologies have been used to study the response of minerals and rocks to shock and dynamic loading as well as high-temperature conditions. We used Seeberger sandstone, Taunus quartzite, Carrara marble, and Weibern tuff as major target rock types. In concert with the experiments we conducted mesoscale numerical simulations of shock wave propagation in heterogeneous rocks resolving the complex response of grains and pores to compressive, shear, and tensile loading and macroscale modeling of crater formation and fracturing. Major results comprise (1) projectile–target interaction, (2) various aspects of shock metamorphism with special focus on low shock pressures and effects of target porosity and water saturation, (3) crater morphologies and cratering efficiencies in various nonporous and porous lithologies, (4) in situ target damage, (5) ejecta dynamics, and (6) geophysical survey of experimental craters.     

Combination of multi-mission altimetry data along the Mekong River with spatio-temporal kriging

River water-level time series at fixed geographical locations, so-called virtual stations, have been computed from single altimeter crossings for many years. Their temporal resolution is limited by the repeat cycle of the individual altimetry missions. The combination of all altimetry measurements along a river enables computing a water-level time series with improved temporal and spatial resolutions. This study uses the geostatistical method of spatio-temporal ordinary kriging to link multi-mission altimetry data along the Mekong River. The required covariance models reflecting the water flow are estimated based on empirical covariance values between altimetry observations at various locations. In this study, two covariance models are developed and tested in the case of the Mekong River: a stationary and a non-stationary covariance model. The proposed approach predicts water-level time series at different locations along the Mekong River with a temporal resolution of 5 days. Validation is performed against in situ data from four gauging stations, yielding RMS differences between 0.82 and 1.29 m and squared correlation coefficients between 0.89 and 0.94. Both models produce comparable results when used for combining data from Envisat, Jason-1, and SARAL for the time period between 2002 and 2015. The quality of the predicted time series turns out to be robust against a possibly decreasing availability of altimetry mission data. This demonstrates that our method is able to close the data gap between the end of the Envisat and the launch of the SARAL mission with interpolated time series.     

Sub-B″ layering in the Southern Caribbean: The Aruba Gap and Venezuela Basin

Multichannel seismic data in the Aruba Gap region near JOIDES/DSDP Site 153 verify the presence of a deep sub-B″ reflection. One multichannel seismic line trends NE-SW on and along the edge of Beata Ridge and passes within 1 km of Site 153, and another line runs N-S across the entire Aruba Gap with the drill site 4 km east from its northern end. Closely spaced velocity analyses indicate the presence of deep primary reflection events and enable calculation of interval velocities between the A″-B″ marker horizons. Deconvolved, true amplitude, normal incidence profiles sharply delineate the A″-B″ marker horizons and indicate the presence of the sub-B″ reflection event. On the NE-SW line, this deep reflector is best described as a “diffuse” discontinuous zone, relatively horizontal, lying about 0.8 seconds of two-way travel time below the B″ reflector, with an interval velocity of approximately 5.0 km/s between Horizon B″ and this reflection. The N-S line is more complex since the sub-B′' reflection event is masked by a strong internal multiple from the A″-B″ interval. In the central and western Venezuela Basin, deep primary reflections beneath Horizon B″ are also observed on the northern and western sides of what appears to be a major fault zone. This fault zone separates the smooth B″ and sub-B″ reflectors on the northern and western sides of this fault zone from what appears to be typical oceanic basement. The widespread presence of sub-B″ reflections yielding high interval velocities for the section between these events and Horizon B″ suggest that this material is probably igneous in origin.     

An approach for GIS-based statistical landslide susceptibility zonation—with a case study in the Himalayas

Landslide susceptibility zonation (LSZ) is necessary for disaster management and planning development activities in mountainous regions. A number of methods, viz. landslide distribution, qualitative, statistical and distribution-free analyses have been used for the LSZ studies and they are again briefly reviewed here. In this work, two methods, the Information Value (InfoVal) and the Landslide Nominal Susceptibility Factor (LNSF) methods that are based on bivariate statistical analysis have been applied for LSZ mapping in a part of the Himalayas. Relevant thematic maps representing various factors (e.g., slope, aspect, relative relief, lithology, buffer zones along thrusts, faults and lineaments, drainage density and landcover) that are related to landslide activity, have been generated using remote sensing and GIS techniques. The LSZ derived from the LNSF method, has been compared with that produced from the InfoVal method and the result shows a more realistic LSZ map from the LNSF method which appears to conform to the heterogeneity of the terrain.     

Solar Eclipses and the Surface Properties of Water

Earth, Moon, and Planets - During four solar eclipse events (two annular, one total and one partial) a correlation was observed between a change in water surface tension and the magnitude of the...