57 research outputs found
The potential of radar-based ensemble forecasts for flash-flood early warning in the southern Swiss Alps
This study explores the limits of radar-based forecasting for hydrological runoff prediction. Two novel radar-based ensemble forecasting chains for flash-flood early warning are investigated in three catchments in the southern Swiss Alps and set in relation to deterministic discharge forecasts for the same catchments. The first radar-based ensemble forecasting chain is driven by NORA (Nowcasting of Orographic Rainfall by means of Analogues), an analogue-based heuristic nowcasting system to predict orographic rainfall for the following eight hours. The second ensemble forecasting system evaluated is REAL-C2, where the numerical weather prediction COSMO-2 is initialised with 25 different initial conditions derived from a four-day nowcast with the radar ensemble REAL. Additionally, three deterministic forecasting chains were analysed. The performance of these five flash-flood forecasting systems was analysed for 1389 h between June 2007 and December 2010 for which NORA forecasts were issued, due to the presence of orographic forcing. A clear preference was found for the ensemble approach. Discharge forecasts perform better when forced by NORA and REAL-C2 rather then by deterministic weather radar data. Moreover, it was observed that using an ensemble of initial conditions at the forecast initialisation, as in REAL-C2, significantly improved the forecast skill. These forecasts also perform better then forecasts forced by ensemble rainfall forecasts (NORA) initialised form a single initial condition of the hydrological model. Thus the best results were obtained with the REAL-C2 forecasting chain. However, for regions where REAL cannot be produced, NORA might be an option for forecasting events triggered by orographic precipitation
Reconstruction and simulation of an extreme flood event in the Lago Maggiore catchment in 1868
Heavy precipitation on the south side of the central Alps
produced a catastrophic flood in October 1868. We assess the damage and
societal impacts, as well as the atmospheric and hydrological drivers using
documentary evidence, observations and novel numerical weather and runoff
simulations.The greatest damage was concentrated close to the Alpine divide and Lago
Maggiore. An atmospheric reanalysis emphasizes the repeated occurrence of
streamers of high potential vorticity as precursors of heavy precipitation.
Dynamical downscaling indicates high freezing levels (4000 m a.s.l.),
extreme precipitation rates (max. 270 mm 24 h−1) and weather dynamics that agree well with observed
precipitation and damage, and with existing concepts of forced low-level
convergence, mid-level uplift and iterative northeastward propagation of
convective cells. Simulated and observed peak levels of Lago Maggiore differ
by 2 m, possibly because the exact cross section of the lake outflow is
unknown. The extreme response of Lago Maggiore cannot be attributed to low
forest cover. Nevertheless, such a paradigm was adopted by policy makers
following the 1868 flood, and used to implement nationwide afforestation
policies and hydraulic structures.These findings illustrate the potential of high-resolution,
hydrometeorological models – strongly supported by historical methods –
to shed new light on weather events and their socio-economic implications in
the 19th century.</p
Spatial variability of soil physical attributes in sugarcane using different row spacings.
The aim of this study was to determine the impact of harvesting traffic by evaluating the spatial variability of soil physical attributes on a clayey Oxisol under sugarcane cultivation using different row spacing. Two areas of sugarcane production (RB855156 genotype) were planted in autumn 2013, both using conventional planting systems. Treatments were either sugarcane cultivated using: (i) single-row spacing (SR) of 1.50 m; or (ii) double-row spacing (DR) of 0.40 × 1.50 m. Areas using SR spacing occupied a total of 6 ha areas using DR spacing occupied a total of 2 ha. Assessments of soil physical attributes were performed during the summer of 2016 after the second harvest. Soil measurements in each area were done at 100 points using a grid design with dimensions of 10 m long by 5 m wide. Soil sampling was taken from the 0.00-0.10 m layer, from points distributed along the planted row and the machine?s wheel track. The following soil physical attributes were assessed: bulk density, total porosity, macroporosity, microporosity, soil penetration resistance, and water contentat field capacity. Bd and PR in the single-row spacing showed critical values for adequate sugarcane root development. The highest spatial variability of PR and Ma was found in double-row spacing, however, this spacing arrangement promoted a better soil physical conditions
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