Some Common Ingredients for Heavy Orographic Rainfall

Hydrology and Earth System Sciences, 2005

In the EFFS Project, an attempt has been made to develop a general framework to study the predictability of severe convective rainfall events in the presence of orography. Convective activity is embedded in orographic rainfall and can be thought as the result of several physical mechanisms. Quantifying its variability on selected area and time scales requires choosing the best physical representation of the rainfall variability on these scales. The main goal was (i) to formulate a meaningful set of experiments to compute the oscillation of variance due to convection inside model forecasts in the presence of orography and (ii) to give a statistical measure of it that might be of value in the operational use of atmospheric data. The study has been limited to atmospheric scales that span the atmosphere from 2 to 200 km and has been focused on extreme events with deep convection. Suitable measures of the changing of convection in the presence of orography have been related to the physical properties of the rainfall environment. Preliminary results for the statistical variability of the convective field are presented.

Terrestrial, Atmospheric and Oceanic Sciences

Journal of Hydrometeorology, 2015

This paper investigates how atmospheric circulation and orography affect the spatial variability of extreme precipitation in terms of depth–duration–frequency (DDF) curve parameters. To this aim, the Italian territory was considered because it is characterized by a complex orography and different precipitation dynamics and regimes. A database of 1494 time series with more than 20 years of maximum annual precipitation data was collected for the durations of 1, 3, 6, 12, and 24 h. For each data series, the parameters of DDF curves were estimated using a statistical simple scale invariance model. Hence, the combined effect of orography and atmospheric fields on parameter variability was investigated considering the spatial distribution of the parameters and their relation with elevation. The vertically integrated atmospheric moisture flux J was used as a measurement of the principal direction of the vapor transport at a given location. The analysis highlights the variability of DDF par...

QUARTERLY JOURNAL OF THE ROYAL METEOROLOGICAL SOCIETY, 2011

Quantitative precipitation forecasting (QPF) in low-mountain regions is a great challenge for the atmospheric sciences community. On the one hand, orographic enhancement of precipitation in these regions can result in severe flash-flood events. On the other hand, the relative importance of forcing mechanisms leading to convection initiation (CI) is neither well understood nor adequately reproduced by weather forecast models. This results in poor QPF skill, both in terms of the spatial distribution of precipitation and its temporal evolution.

2014

The impact of different atmospheric and topographic conditions on the rainfall distribution around a sin-gle, infinitely long ridge is investigated. The main objective of the study was the understand the conditions that are responsible for commonly observed rainfall patterns like high rainfall yields on the side of the ridge facing the wind and rain-shadows on the lee side. A modified version of MM5, a non-hydrostatic model that is widely used for limited area atmospheric simulations for research and operational purposes, was used for this study. The effects of different mountain ridge dimensions, large-scale wind conditions and large-scale moisture profiles on the amount and distribution of orographic precipitation, were clarified. Ridge height has a positive correlation with the amount of rainfall generated while the ridge width did not show such a clear relationship. Slowing of wind speed resulted in the spreading of rainfall outwards from the mountain peak. Reduction of moisture...

Meteorology and Atmospheric Physics, 2006

A mesoscale three-dimensional (3-D) dynamical model is presented to diagnose orographic rainfall, with particular reference to the Western Ghats (WG) in India. This model has two parts, namely, a dynamical part and a thermodynamical part. In the dynamical part the vertical velocity induced by a mesoscale elliptical orographic barrier has been computed using the perturbation technique. In the thermodynamical part rainfall intensity (RFI) has been computed using the computed vertical velocities, with the help of continuity of moisture and mass. The computed RFI has been compared with observed RFI as well as with that computed by 2-D model. The present study shows that during the southwest monsoon season (SWMS), orographic rainfall enhancement in the WG area appears to be solely due to the vertical shear of the basic flow and its variation with height. Stability appears to have very little influence on it. The spatial distribution of RFI across the barrier shows that there are four regions of maximum rainfall, one primary on the windward side behind the peak of the barrier and three secondary on the leeward side. The symmetry in the locations of these secondary rainfall maxima appears to be critically dependent on the component of basic flow parallel to the major ridge axis of the barrier.

Landform Analysis, 2018

The paper discusses the role of orographic barriers in generating torrential precipitation in mountainous regions in different climatic zones, the Eastern Himalayas (tropical zone with well-developed monsoon activity) and the northern slope of the Carpathians (temperate zone with transitional climate). Attention has been paid to the different altitudes and courses of the orographic ridges as well as their location relative to the prevailing directions of influx of moist air masses. The cases analysed included torrential rains with monsoon circulation from the S–SW direction at the 2–3 km high edge of the Himalayas, with special consideration to the distance from the margin of the mountains and the exposure of the slopes. They generate frequent flood waves, landslides, debris flows and upbuilding of the alluvial cones in the foreland of the mountain barriers. The impact of the orographic barrier is significantly less marked in the Polish Carpathians. In the western part, the compact ...

Environmental Research Communications

Interaction of multiple oscillations of different time scales may result in severe weather events. 8 The presence of orography can modulate the intensity of these events even further. Kerala 9 witnessed one such heavy rainfall event in August, 2018, claiming 483 lives and damages worth 10 INR 200 billion. This study focuses on the peak rainfall duration (13-17 August) when the 11 departure from normal was 42%. Segregating moisture transport into its mean and perturbation 12 terms show that an anomalous moisture channel over the Arabian Sea supplied continuous 13 moisture to the Western Ghats (WG), whereas anomalous wind due to a monsoon depression 14 advected moisture towards the southern peninsula. It is evident in the form of Moisture Flux 15 Convergence (MFC) towers traversing along the Eastern Ghats before merging with the semi-16 permanent MFC feature over the WG. The presence of positive quasi biweekly oscillations and 17 of Intra Seasonal Oscillations (ISO) aggravated the event as they complemented the anomalous 18 moisture transport, with ISO constantly providing winds of the order of 2-3 ms-1. In addition, 19 shedding of MFC towers by the depression is accredited to the synoptic scale oscillation.

Atmospheric Research, 2011

This study aims to perform observational data analyses, including European Centre for Medium-Range Weather Forecasts data, radar reflectivity, rainfall data, and numerical simulations with the Weather Research and Forecasting model to examine the orographic effects on a localized heavy rainfall episode which produced up to 204 and 161.5 mm over southwestern Taiwan on 27 and 28 June 2008, respectively. We found that the continuous inland-transport of moist air or inland-movement of convection from the nearby ocean to southwestern Taiwan occur on both days. The orographic lifting on the moist air and convection generates heavy rainfall over sloped areas on 27 June when the relatively fast southwesterly low-level wind prevails (~10 m s −1). The cool air near the foothill facilitates the new development of convection on the upstream side of the old convection over the slope and produces heavy rainfall over lowlands near the foothill. On 28 June, the convection, which is embedded in a relatively slow southwesterly moist airflow, is enhanced over the low-level convergence areas in the lowlands due to the prevailing southwesterly wind. This wind is deflected by the orographic effect and produces heavy rainfall. In addition, the cool air from sloped areas enhances the offshore flow which interacts with the prevailing wind to strengthen the low-level convergence over lowlands and coasts.