Topographic influence on tornado tracks and frequencies in Arkansas and Wisconsin

Gallimore, Robert Geary,

January 1968

Thesis (M.S.)--University of Wisconsin--Madison, 1968. / eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references.

Tornadoes.

A study of tornadoes and tornado producing synoptic systems

Bradford, Sheila Eunice Kaplan,

January 1969

Thesis (M.S.)--University of Wisconsin--Madison, 1969. / eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references.

Tornadoes.

Simulation of a tornado with a fully compressible cloud model /

Vergara, José A.

January 1997

Thesis (Ph. D.)--University of Maryland, College Park, 1997. / Thesis research directed by Dept. of Meteorology. Includes bibliographical references (leaves 122-134).

Tornadoes

Terrain and tornadogenesis in Georgia (1950-1998)

Lawrimore, Scott Alan

05 1900

No description available.

Tornadoes Georgia

The relationship of storm tracks to the occurrence of tornadoes in Indiana

Crowe, Elizabeth A.

January 1979

In April and May of 1976 an anomalous situation occurred in that no tornadoes were reported for Indiana. This study attempts to determine possible relationships that may have caused the anomalous situation. To better understand the factors surrounding this situation, this study deals with a physical survey of Indiana and a review of literature involving conditions for tornado development. The study tests for relationships between tornadoes, storm tracks, and storm track location relevant to Indiana for the months of March, April, and May, 1955 to 1976, that might suggest reasons for the anomalous situation occurring. Statistical analyses involving correlation tests and analysis of variance, are used to test for possible relationships.

Tornadoes -- Indiana.

School's Out for Weather: Early Dismissal in Public School Districts on Potential Severe Weather Days

Van Meter, Jessica

11 May 2013

Survey responses from 76 public school districts in Mississippi and Alabama, tornado warning data, tornado path data, and county demographic data were used to investigate early dismissals in public schools. There was little agreement among survey responses and this inconsistency supports the idea that each situation is unique and one plan may not be successful for all districts. The highest number of reported dismissals would have resulted in a loss of less than 2% of the total annual class time. A higher number of recent killer tornadoes, a lower level of poverty, and a team rather than individual decision were the three most important variables in determining which districts would dismiss more often. The seven districts that reported not dismissing were all well below the national poverty average. Other important factors included smaller county area, higher number of killer tornadoes since 1950, and serving a county rather than city population.

tornadoes

schools

Tornadoes in Mississippi a county by county community risk assessment /

Clark, Renee Nicole.

January 2003

Thesis (M.S.)--Mississippi State University. Department of Geosciences. / Title from title screen. Includes bibliographical references.

A NUMERICAL INVESTIGATION OF THE FORMATION OF SECONDARY VORTICES IN LABORATORY-SIMULATED TORNADOES.

WALKO, ROBERT LAMBERT.

January 1983

Two numerical models, described in detail herein, have been constructed and used to investigate the formation of secondary vortices in axisymmetrically-forced rotating flows. The particular type of vortex flow examined is that developed in a laboratory vortex simulator where secondary vortices have been produced and extensively studied. The first numerical model generated a collection of steady state, axisymmetric vortex flows based on a range of swirl ratios. The second model tested those flows for instability by simulating the behavior of small amplitude, axially asymmetric, linear perturbations superimposed on the flows: amplification of the perturbations indicated instability whereas damping indicated stability. For those flows found to be unstable, the linear perturbations of various azimuthal wavenumbers were analyzed in detail, and from the perturbation growth rates, structures, phase speeds, and energetics, the nature of the instability could be studied. The results of the instability study show that the vortex is stable for the lowest swirl ratios but that above a certain value, instability persists indefinitely. The most rapidly growing wavenumber shifts steadily with increasing swirl from 1 to around 5 in the swirl range investigated. Growth rates were found to be high enough for secondary vortices to form in the laboratory simulator in just a few seconds. Structurally, the perturbation fields were found to have a helical tilt and to be centered near the radius of maximum vertical vorticity in the axisymmetric vortex. They propagated in the same azimuthal direction as the rotation of the axisymmetric flow, but at a somewhat lower angular velocity at the surface. These linear results are all consistent with observed laboratory behavior. From this, it was concluded that linear theory is capable of explaining many important aspects of secondary vortices. An analysis of the perturbation energy equation revealed that at the higher swirl ratios, the perturbation received most of its energy from the deformation of the axisymmetric flow due to the radial distribution of azimuthal velocity, while for low swirl the primary source was from the radial distribution of the vertical velocity. No other component of the axisymmetric vortex ever contributed more than about 25% of these terms.

Tornadoes -- Mathematical models.

Dynamics of tornado-like vortices /

Deng, Litao,

Unknown Date

Thesis (Ph. D.)--University of Oklahoma, 1993. / Includes bibliographical references (leaves 296-305).

Vortex-motion. Tornadoes.

A pseudo-dual-Doppler analysis of cyclic tornadogenesis /

Dowell, David C.,

January 2000

Thesis (Ph. D.)--University of Oklahoma, 2000. / Includes bibliographical references (leaves 105-115).

Tornadoes. Doppler radar.