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  • 1
    Monograph available for loan
    Monograph available for loan
    Mesoscale meteorology in midlatitudes (2010)
    Chichester [u.a.] : Wiley-Blackwell
    Details Availability
    Call number: AWI A5-13-0029
    Description / Table of Contents: Contents: Series Foreword. - Preface. - Acknowledgments. - List of Symbols. - PART I. GENERAL PRINCIPLES. - 1. What is the Mesoscale?. - 1.1 Space and time scales. - 1.2 Dynamical distinctions between the mesoscale and synoptic scale. - 2. Basic Equations and Tools. - 2.1 Thermodynamics. - 2.2 Mass conservation. - 2.3 Momentum equations. - 2.4 Vorticity and circulation. - 2.5 Pressure perturbations. - 2.6 Thermodynamic diagrams. - 2.7 Hodographs. - 3. Mesoscale Instabilities. - 3.1 Static instability. - 3.2 Centrifugal instability. - 3.3 Inertial instability. - 3.4 Symmetric instability. - 3.5 Shear instability. - PART II. LOWER TROPOSPHERIC MESOSCALE PHENOMENA. - 4. The Boundary Layer. - 4.1 The nature of turbulent fluxes. - 4.2 Surface energy budget. - 4.3 Structure and evolution of the boundary layer. - 4.4 Boundary layer convection. - 4.5 Lake-effect convection. - 4.6 Urban boundary layers. - 4.7 The nocturnal low-level wind maximum. - 5. Air Mass Boundaries. - 5.1 Synoptic fronts. - 5.2 Drylines. - 5.3 Outflow boundaries. - 5.4 Mesoscale boundaries originating from differential surface heating. - 6 Mesoscale gravity waves. - 6.1 Basic wave convections. - 6.2 Internal gravity wave dynamics. - 6.3 Wave reflection. - 6.4 Critical levels. - 6.5 Structure and environments of ducted mesoscale gravity waves. - 6.6 Bores. - PART III. DEEP MOIST CONVECTION. - 7. Convection initiation. - 7.1 Requisites for convection initiation and the role of larger scales. - 7.2 Mesoscale complexities of convection initiation. - 7.3 Moisture convergence. - 7.4 Elevated convection. - 8. Organization of isolated convection. - 8.1 Role of vertical wind shear. - 8.2 Single-cell convection. - 8.3 Multicellular convection. - 8.4 Supercellular convection. - 9. Mesoscale convective systems. - 9.1 General characteristics. - 9.2 Squall line structure. - 9.3 Squall line maintenance. - 9.4 Rear inflow and bow echos. - 9.5 Mesoscale convective complexes. - 10. Hazards associated with deep moisture convection. - 10.1 Tornadoes. - 10.2 Nontornadic, damaging straight-line winds. - 10.3 Hailstorms. - 10.4 Flash floods. - PART IV. OROGRAPHIC MESOSCALE PHENOMENA. - 11. Thermally forced winds in mountainous terrain. - 11.1 Slope winds. - 11.2 Valley winds. - 12. Mountain waves and downslope windstorms. - 12.1 Internal gravity waves forced by two-dimensional terrain. - 12.2 Gravity waves forced by isolated peaks. - 12.3 Downslope windstorms. - 12.4 Rotors. - 13. Blocking of the wind by terrain. - 13.1 Factors that govern whether air flows over or around a terrain obstacle. - 13.2 Orographically trapped cold-air surges. - 13.3 Lee vortices. - 13.4 Gap flows. - PART V. APPENDIX. - A - Radar and its applications. - A.1 Radar basics. - A.2 Doppler radar principles. - A.3 Applications. - References. - Index.
    Description / Table of Contents: Mesoscale Meteorology in Mid-Latitudes presents the dynamics of mesoscale meteorological phenomena in a highly accessible student- friendly manner. The book's clear mathematical treatments are complemented by eye-catching photographs and illustrations. Comprehensive coverage of subjects including boundary layer mesoscale phenomena, orographic phenomena and deep convection is brought together with the latest developments in the field to provide an invaluable resource for mesoscale meteorology students. Mesoscale meteorology in midlatitudes functions as a comprehensive, easy-to-use undergraduate textbook while also providing a useful reference for graduate students, research scientists and weather industry professionals.
    Type of Medium: Monograph available for loan
    Pages: XXI, 407 S. : Ill., zahlr. graph. Darst. u. Kt
    ISBN: 9780470742136
    Series Statement: Advancing weather and climate science
    Branch Library: AWI Library
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  • 2
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    What we know and don’t know about tornado formation (2014)
    American Institute of Physics
    Details
    Publication Date: 2014-09-01
    Print ISSN: 0031-9228
    Electronic ISSN: 1945-0699
    Topics: Physics
    Published by American Institute of Physics
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  • 3
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    CORRIGENDUM (2018)
    American Meteorological Society
    Details
    Publication Date: 2018-04-01
    Print ISSN: 0882-8156
    Electronic ISSN: 1520-0434
    Topics: Geography , Physics
    Published by American Meteorological Society
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  • 4
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    Investigation of Near-Storm Environments for Tornado Events and Warnings (2016)
    American Meteorological Society
    Details
    Publication Date: 2016-11-07
    Description: In this study, a 13-yr climatology of tornado event and warning environments, including metrics of tornado intensity and storm morphology, is investigated with particular focus on the environments of tornadoes associated with quasi-linear convective systems and right-moving supercells. The regions of the environmental parameter space having poor warning performance in various geographical locations, as well as during different times of the day and year, are highlighted. Kernel density estimations of the tornado report and warning environments are produced for two parameter spaces: mixed-layer convective available potential energy (MLCAPE) versus 0–6-km vector shear magnitude (SHR6), and mixed-layer lifting condensation level (MLLCL) versus 0–1-km storm-relative helicity (SRH1). The warning performance is best in environments characteristic of severe convection (i.e., environments featuring large values of MLCAPE and SHR6). For tornadoes occurring during the early evening transition period, MLCAPE is maximized, MLLCL heights decrease, SHR6 and SRH1 increase, tornadoes rated as 2 or greater on the enhanced Fujita scale (EF2+) are most common, the probability of detection is relatively high, and false alarm ratios are relatively low. Overall, the parameter-space distributions of warnings and events are similar; at least in a broad sense, there is no systematic problem with forecasting that explains the high overall false alarm ratio, which instead seems to stem from the inability to know which storms in a given environment will be tornadic.
    Print ISSN: 0882-8156
    Electronic ISSN: 1520-0434
    Topics: Geography , Physics
    Published by American Meteorological Society
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  • 5
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    An Investigation of the Goshen County, Wyoming, Tornadic Supercell of 5 June 2009 Using EnKF Assimilation of Mobile Mesonet and Radar Observations Collected during VORTEX2. Part II: Mesocyclone-Scale Processes Affecting Tornado Formation, Maintenance, and Decay (2016)
    American Meteorological Society
    Details
    Publication Date: 2016-09-01
    Description: Storm-scale and mesocyclone-scale processes occurring contemporaneously with a tornado in the Goshen County, Wyoming, supercell observed on 5 June 2009 during the second Verification of the Origins of Rotation in Tornadoes Experiment (VORTEX2) are examined using ensemble analyses produced by assimilating mobile radar and in situ observations into a high-resolution convection-resolving model. This paper focuses on understanding the evolution of the vertical structure of the storm, the outflow buoyancy, and processes affecting the vertical vorticity and circulation within the mesocyclone that correspond to changes in observed tornado intensity.Tornadogenesis occurs when the low-level mesocyclone is least negatively buoyant relative to the environment, possesses its largest circulation, and is collocated with the largest azimuthally averaged convergence during the analysis period. The average buoyancy, circulation, and convergence within the near-surface mesocyclone (on spatial scales resolved by the model) all decrease as the tornado intensifies and matures. The tornado and its parent low-level mesocyclone both dissipate surrounded by a weakening rear-flank downdraft. The decreasing buoyancy of parcels within the low-level mesocyclone may partly be responsible for the weakening of the updraft surrounding the tornado and decoupling of the mid- and low-level circulation. Although the supply of horizontal vorticity generated in the forward flank of the storm increases throughout the life cycle of the tornado, it is presumably less easily tilted and stretched on the mesocyclone-scale during tornado maturity owing to the disruption of the low-level updraft/downdraft structure. Changes in radar-measured tornado intensity lag those of ensemble Kalman filter (EnKF) mesocyclone vorticity and circulation.
    Print ISSN: 0027-0644
    Electronic ISSN: 1520-0493
    Topics: Geography , Geosciences , Physics
    Published by American Meteorological Society
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  • 6
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    Comparison of the Tornadic and Nontornadic Supercells Intercepted by VORTEX2 on 10 June 2010 (2016)
    American Meteorological Society
    Details
    Publication Date: 2016-09-01
    Description: On 10 June 2010, the second Verification of the Origins of Rotation in Tornadoes Experiment (VORTEX2) armada collected a rare set of observations of a nontornadic and a tornadic supercell evolving in close proximity to each other. The storms and their environments were analyzed using single- and dual-Doppler radar, mobile mesonet, deployable surface mesonet, and mobile sounding data, with the goal of understanding why one supercell produced no tornadoes while the other produced at least two. Outflow temperature deficits were similar for the two storms, both within the normal range for weakly tornadic supercells but somewhat cold relative to significantly tornadic supercells. The storms formed in a complex environment, with slightly higher storm-relative helicity near the tornadic supercell. The environment evolved significantly in time, with large thermodynamic changes and increases in storm-relative helicity, leading to conditions much more favorable for tornadogenesis. After a few hours, a new storm developed between the supercells, likely leading to the demise of the nontornadic supercell before it was able to experience the enhanced environmental conditions. Two tornadoes developed within the single mesocyclone of the other supercell. After the dissipation of the second tornado, rapid rearward motion of low- to midlevel circulations may have inhibited further tornado production in this storm.
    Print ISSN: 0027-0644
    Electronic ISSN: 1520-0493
    Topics: Geography , Geosciences , Physics
    Published by American Meteorological Society
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  • 7
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    Long-Term Morphological Changes in Simulated Supercells Following Mergers with Nascent Supercells in Directionally Varying Shear (2016)
    American Meteorological Society
    Details
    Publication Date: 2016-01-29
    Description: Mergers involving supercells remain a challenge for severe thunderstorm forecasting. In this study, mergers between supercells and ordinary cells (e.g., cells forming in a similar environment but too young to be fully developed supercells) are investigated. A series of numerical experiments are performed using an idealized, homogenous environment supportive of cyclonically rotating, right-moving supercells. Warm bubbles are introduced at different times, resulting in two storms of different maturity; their placement is used to control the location of the merger and the relative maturity of the second storm. Simplified conceptual models for the long-term outcomes of mergers are developed. In the simplest mode of merger, outflow from the new cell cuts off inflow to the original. If the new cell’s cold pool is not sufficiently strong to cut off the inflow to the original cell, the minimum separation of the updraft maxima during the merger becomes a key controlling factor in the outcome. If it is less than 10 km, an updraft collision occurs, resulting in a classic supercell. If it is greater than 20 km and the new cell merges into the original cell’s forward flank, a dual-cell system results. If it is between 10 and 20 km, the enhanced precipitation produced during the merger leads to a cold pool surge and an updraft bridge, joining the original updrafts and developing into either a small bow echo (with forward-flank mergers) or a supercell on the classic high-precipitation spectrum (with rear-flank mergers), depending on the distribution of precipitation in the merging system.
    Print ISSN: 0027-0644
    Electronic ISSN: 1520-0493
    Topics: Geography , Geosciences , Physics
    Published by American Meteorological Society
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  • 8
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    Aboveground Thermodynamic Observations in Convective Storms from Balloonborne Probes Acting as Pseudo-Lagrangian Drifters (2018)
    American Meteorological Society
    Details
    Publication Date: 2018-04-01
    Description: The severe storms research community lacks reliable, aboveground, thermodynamic observations (e.g., temperature, humidity, and pressure) in convective storms. These missing observations are crucial to understanding the behavior of both supercell storms (e.g., the generation, reorientation, and amplification of vorticity necessary for tornado formation) and larger-scale (mesoscale) convective systems (e.g., storm maintenance and the generation of damaging straight-line winds). This paper describes a novel way to use balloonborne probes to obtain aboveground thermodynamic observations. Each probe is carried by a pair of balloons until one of the balloons is jettisoned; the remaining balloon and probe act as a pseudo-Lagrangian drifter that is drawn through the storm. Preliminary data are presented from a pair of deployments in supercell storms in Oklahoma and Kansas during May 2017. The versatility of the observing system extends beyond severe storms applications into any area of mesoscale meteorology in which a large array of aboveground, in situ thermodynamic observations are needed.
    Print ISSN: 0003-0007
    Electronic ISSN: 1520-0477
    Topics: Geography , Physics
    Published by American Meteorological Society
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  • 9
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    Self-Organizing Maps for the Investigation of Tornadic Near-Storm Environments (2017)
    American Meteorological Society
    Details
    Publication Date: 2017-07-13
    Description: In this work, self-organizing maps (SOMs) are used to investigate patterns of favorable near-storm environmental parameters in a 13-yr climatology of 14 814 tornado events and 44 961 tornado warnings across the continental United States. Establishing nine statistically distinct clusters of spatial distributions of the significant tornado parameter (STP) in the 480 km × 480 km region surrounding each tornado event or warning allows for the examination of each cluster in isolation. For tornado events, distinct patterns are associated more with particular times of day, geographical locations, and times of year. For example, the archetypal springtime dryline setup in the Great Plains emerges readily from the data. While high values of STP tend to correspond to relatively high probabilities of detection (PODs) and relatively low false alarm ratios (FARs), the majority of tornado events occur within a pattern of uniformly lower STP, with relatively high FAR and low POD. Overall, the two-dimensional plots produced by the SOM approach provide an intuitive way of creating nuanced climatologies of tornadic near-storm environments.
    Print ISSN: 0882-8156
    Electronic ISSN: 1520-0434
    Topics: Geography , Physics
    Published by American Meteorological Society
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  • 10
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    Large Sensitivity of Near-Surface Vertical Vorticity Development to Heat Sink Location in Idealized Simulations of Supercell-Like Storms (2017)
    American Meteorological Society
    Details
    Publication Date: 2017-03-28
    Description: In idealized numerical simulations of supercell-like “pseudostorms” generated by a heat source and sink in a vertically sheared environment, a tornado-like vortex develops if air possessing large circulation about a vertical axis at the lowest model levels can be converged. This is most likely to happen if the circulation-rich air possesses only weak negative buoyancy (the circulation-rich air has a history of descent, so typically possesses at least some negative buoyancy) and is subjected to an upward-directed vertical perturbation pressure gradient force. This paper further explores the sensitivity of the development of near-surface vertical vorticity to the horizontal position of the heat sink. Shifting the position of the heat sink by only 2–3 km can significantly influence vortex intensity by altering both the baroclinic generation of circulation and the buoyancy of circulation-rich air. Many of the changes in the pseudostorms that arise from shifting the position of the heat sink would be difficult to anticipate. The sensitivity of the pseudostorms to heat sink position probably at least partly explains the well-known sensitivity of near-surface vertical vorticity development to the microphysics parameterizations in more realistic supercell storm simulations, as well as some of the failures of actual supercells to produce tornadoes in seemingly favorable environments.
    Print ISSN: 0022-4928
    Electronic ISSN: 1520-0469
    Topics: Geography , Geosciences , Physics
    Published by American Meteorological Society
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