Severe Weather during the North American Monsoon and Its Response to Rapid Urbanization and a Changing Global Climate within the Context of High Resolution Regional Atmospheric Modeling

Luong, Thang Manh

January 2015

The North American monsoon (NAM) is the principal driver of summer severe weather in the Southwest U.S. With sufficient atmospheric instability and moisture, monsoon convection initiates during daytime in the mountains and later may organize, principally into mesoscale convective systems (MCSs). Most monsoon-related severe weather occurs in association with organized convection, including microbursts, dust storms, flash flooding and lightning. The overarching theme of this dissertation research is to investigate simulation of monsoon severe weather due to organized convection within the use of regional atmospheric modeling. A commonly used cumulus parameterization scheme has been modified to better account for dynamic pressure effects, resulting in an improved representation of a simulated MCS during the North American monsoon experiment and the climatology of warm season precipitation in a long-term regional climate model simulation. The effect of urbanization on organized convection occurring in Phoenix is evaluated in model sensitivity experiments using an urban canopy model (UCM) and urban land cover compared to pre-settlement natural desert land cover. The presence of vegetation and irrigation makes Phoenix a "heat sink" in comparison to its surrounding desert, and as a result the modeled precipitation in response to urbanization decreases within the Phoenix urban area and increase on its periphery. Finally, analysis of how monsoon severe weather is changing in association with observed global climate change is considered within the context of a series of retrospectively simulated severe weather events during the period 1948-2010 in a numerical weather prediction paradigm. The individual severe weather events are identified by favorable thermodynamic conditions of instability and atmospheric moisture (precipitable water). Changes in precipitation extremes are evaluated with extreme value statistics. During the last several decades, there has been intensification of organized convective precipitation, but these events occur with less frequency. A more favorable thermodynamic environment for monsoon thunderstorms is the driver of these changes, which is consistent with the broader notion that anthropogenic climate change is presently intensifying weather extremes worldwide.

extreme value statistic

mesoscale convective system

North American monsoon

severe weather

urbanization

Atmospheric Sciences

cumulus parameterization

Verification of the Weather Research and Forecasting Model for Alberta

Pennelly, Clark William

Unknown Date

No description available.

WRF

forecast verification

skill score

precipitation

cumulus parameterization

Weather Research and Forecasting

Numerical weather prediction

AVALIAÇÃO DA PREVISÃO NUMÉRICA SAZONAL DE PRECIPITAÇÃO PARA O RIO GRANDE DO SUL / EVALUATION FORECAST NUMERICAL OF SEASONAL PRECIPITATION FOR THE RIO GRANDE DO SUL

Gonçalves, Jéssica Stobienia

04 March 2015

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / In order to obtain an increase of quality seasonal climate forecast of precipitation, for the state of Rio Grande do Sul, were implemented and evaluated nine types of simulations that uses different cumulus parameterization schemes available in the Regional Climate Model version 4 RegCM4.The tested parameterizations were Grell with closure Arakawa and Schubert - AS and Fritsch and Chappell - FC, MIT-Emanuel and mixed convection that is the use of different convection schemes on the land and the sea. The evaluation method consisted of analysis qualitative and quantitative statistics of seasonal precipitation climate forecasts of five regions of Rio Grande do Sul, from August 2013 to August 2014.The statistics applied were Taylor diagram, random and systematic error analysis, concordance index and contingency table. The forecasts were evaluated using observed data from meteorological stations of the Instituto Nacional de Meteorogia (INMET). The analysis showed the RegCM4 had higher correlations and lower errors compared to the Global Model. The best results were observed in the northern and western part of the state with the parameterizations Grell FC, Grell AS and the combination of Emanuel simulated ocean and Grell AS on land. Although some regions were not adequately represented by the Regional Climate Model RegCM4, yet it performed well reducing the overestimation of precipitation observed in the simulation of the Global Model and improved temporal distribution of the same. / Com a finalidade de se obter uma previsão climática sazonal de precipitação de qualidade para o Estado do Rio Grande do Sul foram realizadas e avaliadas nove tipos de simulações que utilizam diferentes esquemas de parametrização cumulus, disponíveis no Modelo Regional Climático RegCM versão 4. As parametrizações testadas foram Grell com fechamento Arakawa e Schubert - AS e Fritsch e Chappell FC, MIT-Emanuel e convecção mista que é a utilização dos diferentes esquemas de convecção sobre a terra e o mar. O método de avaliação consistiu de análises estatísticas qualitativas e quantitativas das previsões climáticas de precipitação sobre cinco regiões do Rio Grande do Sul no período de agosto de 2013 a agosto de 2014. As estatísticas aplicadas foram Diagrama de Taylor, análise de erro aleatório e sistemático, índice de concordância e tabela de contingência. As previsões foram avaliadas através dos dados observados de estações meteorológicas do Instituto Nacional de Meteorologia. As análises mostraram que o RegCM4 apresentou correlações maiores e erros menores em comparação com o Modelo Global. Os melhores resultados foram observados na metade norte e oeste do Estado com as parametrizações Grell FC, Grell AS e a combinação de Emanuel simulado sobre o oceano e Grell AS sobre a terra. Apesar de algumas regiões não terem sido representadas adequadamente pelo Modelo Regional Climático RegCM4, ainda assim ele teve um bom desempenho em reduzir as superestimações de precipitação observadas na simulação do Modelo Global e melhora na distribuição temporal da mesma.

Previsão Climática

Precipitação

Parametrização Cumulus

Climate Forecasting

Precipitation

Cumulus parameterization

The influence of topography and model grid resolution on extreme weather forecasts over South Africa

Maisha, Thizwilondi Robert

January 2014

The topography of South Africa (SA) shows complex variations and is one the main factors that determine the daily weather patterns and climate characteristics. It affects for example temperature, winds and rainfall (intensity and distribution). Mesoscale numerical weather prediction (NWP) models are used to simulate atmospheric motions with high horizontal grid resolution using appropriate cumulus parameterisation schemes. They also allow users to investigate the effects of topography and surface heating on the development of convective systems. The Weather Research and Forecasting (WRF) model was applied over the complex terrain of SA to simulate extreme weather events and evaluate the influence of topography and grid resolution on the accuracy of weather simulations. This includes heavy precipitation event that lead to floods over Limpopo region of SA which was caused by the tropical depression Dando for the period 16 -18 January 2012; the heat wave events over Limpopo region for the period 22-26 October 2011 and also over Cape region for the period 15-18 January 2012. The Grell-Devenyi Ensemble (GDE) cumulus parameterization scheme was applied. The WRF model was run at a horizontal resolution of 9 km with 3 km nests, one over Limpopo and another over Cape region respectively. A total of 210 South African Weather Service (SAWS) synoptic stations data were used to verify the model, with 37 stations located over Limpopo and 88 over Cape region. The WRF model simulations are able to capture the spatial and temporal distribution of the heat wave over Limpopo and Cape regions respectively. The model verification with observational data showed that the performance statistics are in the expected range. The experiments without topography give unrealistic verification scores. The increase of model grid resolution from 9 to 3 km improved the spatial and temporal distribution and performance statistics. The above findings are in general similar for the two heat wave events, although the influence of topography over Cape region is not too pronounced. This can be attributed to different topographic variations over the Cape region as compared to the Limpopo region. The WRF model captured well the spatial and temporal distribution of rainfall patterns; verification statistics shows over-prediction of its intensity in simulation with topography. The simulation without topography shows unrealistic space and intensity of rain distribution. An increase in model grid resolution from 9 to 3 km shows improved spatial and temporal distribution of rainfall. The importance of high grid resolution and the use of non-hydrostatic equations are confirmed by the analysis of the vertical velocity distribution and moisture fluxes. The overall findings proved that topography plays a major role to weather and climate over SA. The high grid resolution allows for a better topography representation and capturing convective activities by the use of nonhydrostatic approximations. Therefore the WRF model proved to be useful forecasting tool for weather and climate simulations and can be used for operational weather forecasting over South Africa. / Dissertation (MSc)--University of Pretoria, 2014. / lk2014 / Geography, Geoinformatics and Meteorology / MSc / Unrestricted

Topography of SA

Mesoscale models

Numerical weather prediction

Cumulus parameterization

High grid resolution

UCTD

Application of the Weather Research and Forecasting (WRF) Model to Simulate a Squall Line: Implications of Choosing Parameterization Scheme Combinations and Model Initialization Data Sets

Gaines, Mitchell

01 August 2012

On January 29-30, 2008 a squall line of thunderstorms moved through the Ohio Valley resulting in four deaths and one injury. Such events highlight the importance of accurate forecasting for public safety. Mesoscale Modeling plays an important role in any forecast of a potential squall line. The focus of this study was to examine the performance of several parameterization scheme combinations in the Weather Research and Forecasting Model version three (WRF) as they related to this event. These examinations included cloud microphysics (WRF Single-Moment 3-class, 6-class, and Goddard), cumulus parameterization (Kain-Fritsch and Bets-Miller-Janjic) and planetary boundary layer schemes (Yonsei-University and Mellor-Yamada-Janjic). A total of 12 WRF simulations were conducted for all potential scheme combinations. Data from the WRF simulations for several locations in south central Kentucky were analyzed and compared using Kentucky Mesonet observations for four locations: Bowling Green, Russellville, Murray and Liberty, KY. A fine model resolution of 1 km was used over these locations. Coarser resolutions of 3 km and 9 km were used on the outer two domains, which encompassed the Ohio and Tennessee Valleys. The model simulation performance was assessed using established statistical measures for the above four locations and by visually comparing the North American Regional Reanalysis dataset (NARR) along with modeled simulations. The most satisfactory scheme combination was the WRF Single-Moment 3-class Microphysics scheme, Kain-Fritsch cumulus parameterization scheme and Yonsei University scheme for the planetary boundary layer. The planetary boundary layer schemes were noted to have the greatest influence in determining the most satisfactory model simulations. There was limited influence from different selections of microphysics and cumulus parameterization schemes. The preferred physics parameters from these simulations were then used in six additional simulations to analyze the affect different initialization data sets have with regards to model output. Data sets used in these simulations were the Final Operational Analysis global data, North American Regional Reanalysis (3 and 6 hour) and the North American Mesoscale Model at 1, 3 and 6 hour timesteps, for a total of six simulations. More timesteps or an increase in model resolution did not materially improve the model performance.

meterology

computer modeling

Ohio Valley thunderstorms

cumulus parameterization schemes

Kain-Fritsch

Bets-Miller-Janjic

planetary boundary layer schemes

Kentucky Mesonet sites

Meteorology

Regional Precipitation Study in Central America, Using the WRF Model

Maldonado, Tito

January 2012

Using the regional climate model WRF, and the NCEP-NCAR Reanalysis Project data asboundary and initial conditions, regional precipitation was estimated by means of thedynamical downscaling technique for two selected periods, January 2000 and September2007. These months show very particular climatic characteristics of the precipitationregimen in Central America, like dry (wet) conditions in the Pacific (Caribbean) coast of theCentral American isthmus, in January, and wet (dry) conditions, respectively in each coast,during September. Four-nested-domains, each grids of resolution of 90 km (d01), 30 km(d02), 10 km (d03), and 3.3 km (d04), were configured over this region. The runs werereinitialized each 5 days with 6 hours of spin-up time for adjustment of the model. A total of8 experiments (4 per month) were tested in order to study: a) two important CumulusParameterization Schemes (CPS), Kain-Fritsch (KF) and Grell-Devenyi (GD); and b) thephysical interaction between nested domains (one- and two-way nesting), during eachsimulated month.January 2000 results showed that the modeled precipitation is in agreement withobservations, and also captured the mean climate features of rainfall concerning magnitude,and spatial distribution, like the particular precipitation contrast between the Pacific and theCaribbean coast.Outputs from September 2007 revealed significant differences when a visual comparison ismade to the spatial distribution of each coarse domain (d01, d02, and d03) with theirrespective domain in each experiment. However, the inner grids (d04) in all theexperiments, showed a similar spatial distribution and magnitude estimation, mainly inthose runs using one-way nesting configuration. Furthermore, the results for this mothdiffer substantially with observations, and the latter could be related with associateddeficiencies in the boundary condition that do not reproduce well the transition periodsfrom warm to cold El Niño episodes.Moreover, in all the experiments, the KF scheme calculated more precipitation than the GDscheme and it is associated to the ability of the GD scheme to reproduce spotty but intenserainfall, and apparently, this scheme is reluctant to activate, frequently yielding little or norain. However, when rainfall does develop, it is very intense.Also, the time series do not replicate specific precipitation events, thus, the 5-daysintegration period used in this study, is not enough to reproduce short-period precipitationevents.Finally, physical interaction issues between the nested domains are reflected indiscontinuities in the precipitation field, which have been associated to mass fieldadjustment in the CPS. / Nederbörden i Central Amerika har uppskattats med dynamisk nedskalning för två utvaldaperioder, januari 2000 och september 2007. Global återanalysdata från NCEP-NCARsåteranalysprojekt har använts som randdata och initialdata till den regionalaklimatmodellen WRF. De studerade månaderna uppvisar stora variationer inederbördsmönster, t ex lite (mycket) nederbörd under januari och mycket (lite) nederbördunder september för kustområdena längs Stilla havet (Karibiska havet). Fyra nästladedomäner över Central Amerika har använts med en upplösning på 90 km (d01), 30 km (d02),10 km (d03) och 3,3 km (d04). Simuleringarna initialiserades var 5:e dag och de första 6timmarna efter varje initialisering används för modellens anpassning till initialtillståndet.Totalt 8 experiment genomfördes (4 för varje månad) för att studera: (a) två olika sätt attparameterisera konvektion i Cumulusmoln (CPS), Kain-Fritsch (KF) och Grell-Devenyi (GD)och (b) den fysikaliska interaktionen mellan de nästlade domänerna (en- respektive tvåvägsnästlade scheman).För januari 2000 var det god överensstämmelse mellan modellerad och observeradnederbörd. Modellen beskriver väl såväl mängden nederbörd som den rumsligafördelningen, t ex den stora kontrasten mellan kustområdena längs Stilla havet och Karibiskahavet.För september 2007 uppvisar den modellerade nederbörden stora skillnader i de olikaexperimenten för de yttre domänerna (d01, d02, d03). För den inre domänen (d04) ärresultaten från de olika experimenten betydligt mer lika, särskilt för experimenten medenvägs nästlade scheman. Vidare skiljer sig den modellerade nederbörden väsentligt frånobserverad nederbörd under september 2007. Detta kan förklaras med felaktiga randdatapå grund av problemet i återanalys data att reproducera perioder med övergång från varmtill kall El Niño. I alla experiment gav KF mer nederbörd än GD, det kan förklaras med att GDbättre reproducerar kortvarig, intensiv nederbörd. Det finns en viss tröghet innannederbörden i GD aktiveras, vilket innebär större frekvens av lite eller ingen nederbörd. Närnederbörden väl utvecklas blir den dock intensiv. WRF-modellen klarar inte av att återgespecifika nederbördshändelser för de genomförda experimenten, vilket betyder att 5-dagarär för lång simuleringstid för att kunna reproducera specifika händelser. Slutligen,interaktion mellan de nästlade domänerna skapar diskontinuiteter i nederbördsmöns.

WRF

Central America

precipitation

dynamical downscaling

regional models

reanalysis

cumulus parameterization schemes.

WRF

Centralamerika

nederbörd

dynamiska nedskalning

regionala modeller

reanalys

cumulus parametrisering system