A numerical investigation of the transformation of a long-lived mesovortex into a tropical storm /

Bao, Ning, 1961-

January 1999

The evolution of a long-lived mesovortex and its transformation into a tropical storm are studied by a three dimensional mesoscale model. The major aspects of the work are: (1) to demonstrate the mesoscale predictability of a long-lived mesoscale convective system (MCS) from a mid-level vortex over land to a tropical storm over ocean, (2) to understand the processes involved in the transformation of a mid-level continental vortex into a tropical storm, and (3) to perform sensitivity experiments to assess the impact of model physics on an idealized simulation. / The major conclusions are: The 90-h real-data simulation shows that the mesoscale model reproduces very well much of the meso-beta-structures and the evolution of the long-lived MCS. These include the development and dissipation of the continental mesovortex, the initiation of a new MCS both in time and in space, the genesis of a surface mesolow over the warm Gulf Stream water, the track and the deepening of the surface cyclone into a "tropical storm", the maintenance of a mid-level mesovortex system, and the propagation of a large-scale cold front with respect to the surface cyclone. / The simulation also shows that the mid-level mesovortex provides persistent convergence at its southern periphery for the continued convective development, whereas the convectively enhanced low-level flow increases surface energy fluxes over the warm water causing further conditional instability. Such feedback processes lead to the rapid deepening of the "tropical storm". / An idealized simulation was performed to eliminate the possible influence of the cold frontal system on the genesis of the tropical storm. The initial conditions resemble the basic structure of the subtropical high in the real-data case, but without the embedded frontal system. The simulation reproduces almost all of the essential features in the real-data simulation. In particular, the eye-like warm core structure of the tropical storm is well simulated. By decomposing the vertical relative vorticity into the curvature vorticity and the shear vorticity, it is shown that the amplification of a low-level vortex after 36 h arises mainly from the increase of curvature vorticity. The quasi-Lagrangian theta budget calculation shows that the descending motion in the center of the surface cyclone contributes to the formation of the warm core at 800 hPa. / The results of sensitivity experiments demonstrate the impact of model physics on the idealized simulation. Using the Betts-Miller scheme, we showed that the model fails to simulate the multiple-episodes of convective activity which are present in observational studies of tropical cyclogenesis and in the simulation using the Kain-Fritsch scheme. We further found that the surface latent heat fluxes represent a dominant factor in the production of CAPE to maintain the persistent convection. Finally, we discussed the cumulative cooling effect by long-wave radiation on the destabilization of the environment of the storm.

Physics, Atmospheric Science.

Correlations and multifractal measures

Matte, Robert

January 1992

This thesis explores the relationships between multifractal measures, multiplicative cascades and correlations. A review of fractal geometry, multifractal formalism and multiplicative cascades is offered. The importance of the Legendre transformation in multifractal formalism is highlighted, especially for multifractal spectrums which are not convex or twice differentiable. By reconsidering the scaling assumption $N sb{p}( alpha$) d$ alpha$ = $ sigma( alpha) rho sp{-f( alpha)} d alpha$, we show that subsets of a measure may offer a different multifractal spectrum. A gradation of self-similarity and scaling vis-a-vis canonicity is offered. Localized and generalized correlations are introduced, and two-point correlations are revisited for multiplicative cascades. A three-point correlation function is presented and discussed. The presence of an integral scale is shown to produce a more involved correlation scaling behaviour.

Mathematics.

Physics, Atmospheric Science.

Numerical experiments on entrainment, mixing and their effect on cloud dropsize distributions in a cumulus cloud

Vaillancourt, Paul

January 1992

Entrainment, extreme inhomogeneous mixing, in the presence of wind shear, and their effect on cloud droplet spectra are investigated. A dynamical model in conjunction with a microphysical model designed to predict evolution of cloud droplet spectra, is employed to perform a two-dimensional simulation of a small nonprecipitating cumulus cloud in the presence of wind shear. / Results show that vortex circulations and penetrative downdrafts are responsible for entrainment of clear air into the cloud structure. Entrainment and mixing are more severe on the downshear side of the cloud leading to a more fragmented structure and often to total dissipation of cloudy air rather than partial dilution as is the case on the upshear side. Mixing followed by uplifting leads to fresh activation of cloud droplets and results in multimodal spectra. In areas where mixing has occurred, the spectra exhibit smaller average radius and larger standard deviation.

Physics, Atmospheric Science.

Precipitation estimates by radar : a zenith pointing radar perspective

Fabry, Frédéric

January 1990

Data collected from zenith pointing radar is used to study the range dependence of some meteorological radar errors associated with different sampling methods between radar and gauges in stratiform precipitation. Errors due to the vertical variation of reflectivity such as those related with the bright band or with snow growth cause a much larger bias in radar estimates than those due to beam filling or gradients. The maximum useful range varies with the bright band height and the elevation angle program used, a CAPPI giving superior results especially for snow. The sudden changes in bright band height over short distances and the large scatter of its thickness limit the accuracy of current corrections for the vertical variation of reflectivity based on scanning radar data. The possibility of using a zenith pointing radar to obtain this correction is discussed.

Physics, Atmospheric Science.

On the detection of cirrus clouds from satellite measurements

Di Girolamo, Larry

January 1992

A thorough literature review of cloud algorithm validation strategies is presented, with particular emphasis on the problems of detecting cirrus clouds. To further advance our cirrus detection capabilities, a new cloud detection technique is proposed for the Multi-angle Imaging Spectro-Radiometer (MISR), which is scheduled to be on the first platform of the Earth Observing System. Radiative Transfer simulations have been used to develop a Band-Differenced Angular Signature technique. This new technique takes the difference between two solar spectral reflectances as a function of view angle. The resulting angular signature is used to discriminate between high- and low-level clouds and surface reflectance anomalies. This technique, coupled with a Predetermined Clear Sky Threshold developed in this study for MISR, can detect cirrus clouds of visible optical thickness $>$0.5 without any a priori knowledge of atmospheric conditions. Other techniques that can be used with MISR (i.e. stereo) are also discussed.

Physics, Atmospheric Science.

A reanalysis of hurricane Hazel (1954) /

Weese, Scott R.

January 2003

Hurricane Hazel struck North America on 15-16 October 1954, leaving a pattern of heavy rainfall and flooding in its wake. A complete analysis of the synoptic-scale conditions associated with the transformation of Hazel from its tropical phase into an extratropical cyclone was first undertaken to discern the dynamic and thermodynamic elements crucial to the intensification of this storm. / An analogue search was then conducted for Hazel using linear correlations of anomaly sea level pressure and 1000-500 hPa thickness. Three cases were found in 1985, 1995 and 1999. A comparison of these analogues to Hazel yielded the conclusion that Hazel is a unique event in recent meteorological history, as none of the analogues produces the extreme precipitation values in Hazel. The lack of significant hurricane circulations in all of the analogues is the important difference, as Hazel provides important moisture and latent heating that are absent in the analogues. / Finally a mesoscale modeling study was carried out to test the sensitivity of Hazel to improved surface vortex structure and increased horizontal resolution. Specification of the vortex led to a dramatic improvement in the simulation results, as precipitation and track closely mimicked the observed values. Enhancing the horizontal resolution to 12 km did not improve upon the 36 km specified vortex simulation. The movement of the storm slowed considerably as the development of an upper tropospheric cutoff circulation was diminished in the 12 km run. The parameterizations governing the interaction between the diabatic outflow from Hazel and dynamics of the midlatitude trough are poorly modeled in this situation, and lead to the severe time lag in the path of Hazel.

Physics, Atmospheric Science.

The influence of sea surface temperature anomalies on the extra-tropical atmosphere : a winter and spring analysis

Dumas, Karine

January 2004

Ensemble of seasonal forecasts done with four atmospheric models over 26 winters and springs (1969-1994) are used to investigate the Northern Hemispheric model responses to SST anomalies and to compare them with observations. The response, for winter (DJF) and spring (MAM), is obtained as the regression of the 500hPa geopotential heights against the main modes of sea surface temperature (SST) variability over two different regions of the world oceans. The regression against the main mode of the equatorial Pacific Ocean SST, takes the expected form of the Pacific-North-America (PNA) pattern both in models and observations. The response to the North Atlantic SST is an AO/NAO-like signal for the observations and also, to varying degrees, for the models. The similarity of the regression to the third mode of equatorial Pacific SST and to the first mode of North Atlantic SST during the spring season is discussed, along with the nonlinear features of the ENSO influence.

Physics, Atmospheric Science.

Upflowing auroral ion conics observed by the TIDE and TIMAS instruments on the ISTP/POLAR spacecraft

Huddleston, Matthew Mark

January 1999

Acceleration of ions transverse to the local magnetic field is ultimately necessary for gravitationally bound ionospheric plasma to escape out to the magnetosphere. Transversely accelerated ions (TAI's), which take the form of upflowing "conical" ion distributions, are not completely understood and are the subject of this thesis. TIDE and TIMAS are highly sensitive ion mass spectrometers carried by NASA's Polar spacecraft and capable of exceptional temporal, spatial, and energy resolution. Polar's elliptical orbit allows these instruments to sample auroral outflows at low altitudes near common source regions of transverse energization and also at high altitudes where conics are rarely reported. Four conic events observed by both TIDE and TIMAS are compared with several possible acceleration mechanisms. Low altitude conics are found to be the result of resonant wave-particle heating, while high altitude transverse distributions appear to arise from acceleration through small-scale electromagnetic structures.

Physics, Atmospheric Science

A moisture transport and precipitation parameterization for energy balance climate models

Chu, Shaoping

January 1992

The spatial distribution of water in all its three phases is an important factor in determining the climate. The interactions among temperature, water vapor, infrared emission and solar radiation form a series of feedback mechanisms, which play a very important role in the climate system. In order to trace moisture flow through the climate system and examine its impact on climate, a parameterization for the computation of moisture transport and precipitation is developed, one that will eventually be incorporated into a coupled energy balance climate-thermodynamic sea ice model (the CCSI model). This parameterization is tested by comparing computed energy transports and precipitation rates with available observations and by evaluating its sensitivity to variations in the values of specified parameters. The results of these studies indicate that the moisture parameterization is somewhat sensitive to variations in wind speed, surface air temperature and moisture flux, while it is relatively insensitive to changes in relative humidity. In general this parameterization does a good job in simulating the seasonal cycle and latitudinal distribution of the wind speed, moisture transport and precipitation when compared to the observed data and general circulation model (GCM) results.

Physics, Atmospheric Science

An analysis of lightning and the limitations it imposes on a global model of thunderstorm electricity

Geis, Paul B.

January 1990

I report here on preliminary work incorporating transient effects from lightning into a global thunderstorm electricity model. First, E, the electric field produced by a lightning return stroke, is analytically derived. Second, a determination is made of the model's ability to handle the quickly varying fields produced by lightning. In solving for the conduction current and other quantities of interest in the atmosphere the contribution to E from the vector potential is ignored. This approximation is most likely to be invalidated by the electric fields associated with lightning. We calculate the electric field component due to the vector potential, and the conduction current this electric field drives. The conduction current driven by the lightning flash is small compared to the other currents present for the time scales of importance in the model, and can be ignored. Therefore the model is able to include the effect of lightning on the global electric circuit even though the radiation component of the lightning is explicitly absent. A test of the model's accuracy, the continuity of current test, shows the model's results are self-consistent to within 9%-17%, depending upon the region being studied.

Physics, Atmospheric Science