Your search keyword '"Johns, Robert"' showing total 4 results

1. Comments on `A Climatology of Derecho-Producing Mesoscale Convective Systems in the Central and...

Author

Johns, Robert H. and Evans, Jeffry S.

Subjects

*CONVECTIVE clouds, *CLIMATOLOGY

Abstract

Comments on the research paper `A Climatology of Derecho-Producing Mesoscale Convective Systems in the Central and Eastern United States, 1986-95. Part I: Temporal and Spatial Distribution.' Insufficiency of the data to prove that the warm-season high-frequency axis in the mid-Atlantic states is a climatological distribution for warm-season derechos.

Published

2000

2. Extratropical Cyclones with Multiple Warm-Front-Like Baroclinic Zones and Their Relationship to Severe Convective Storms.

Author

Metz, Nicholas D., Schultz, David M., and Johns, Robert H.

Subjects

*WEATHER, *WEATHER forecasting, *CLIMATOLOGY, *METEOROLOGICAL precipitation, *CYCLONES, *STORMS

Abstract

Extratropical cyclones over the central United States and southern Canada from the years 1982 and 1989 were examined for the presence of two or more (multiple) warm-front-like baroclinic zones, hereafter called MWFL baroclinic zones. Of the 108 cyclones identified during this period, 42% were found to have MWFL baroclinic zones, where a baroclinic zone was defined as a magnitude of the surface temperature gradient of 8°F (4.4°C) 220 km-1 over a length of at least 440 km. The largest frequency of cyclones with MWFL baroclinic zones occurred during April, May, August, and September. Ninety-four percent of all baroclinic zones were coincident with a magnitude of the dewpoint temperature gradient of at least 4°F (2.2°C) 220 km-1, and 81% of all baroclinic zones possessed a wind shift of at least 20°, suggesting that these baroclinic zones were significant airmass and airstream boundaries. Although cyclones with MWFL baroclinic zones formed in a variety of ways, two synoptic patterns dominated. Thirty-eight percent of cyclones with MWFL baroclinic zones formed as a cold or stationary front from a previous cyclonic system was drawn into the circulation of a cyclone center, forming the southern baroclinic zone. Twenty-two percent of cyclones with MWFL baroclinic zones formed as a cold front to the north of the cyclone center was drawn into the circulation of the cyclone, forming the northern baroclinic zone. Other synoptic patterns included outflow boundaries (9%), chinook fronts (4%), return flow from the Gulf of Mexico (4%), and unclassified (22%). Although the frequency of severe weather in cyclones was roughly the same for cyclones with and without MWFL baroclinic zones, the presence of the southern baroclinic zone provided a mechanism to focus the location of severe weather, showing their utility for severe weather forecasting. Despite the potential for severe convective storms along these southern baroclinic zones, 51% were not identified on the National Meteorological Center (now known as the National Centers for Environmental Prediction) surface analyses, indicating the importance of performing real-time surface isotherm analysis. [ABSTRACT FROM AUTHOR]

Published

2004

3. CORRIGENDUM.

Author

Sears-Collins, Addison L., Schultz, David M., and Johns, Robert H.

Subjects

*CLIMATOLOGY

Abstract

A correction to the article "The spatial and temporal variability of drizzle in the United States and Canada" that was published in the 2006 issue is presented.

Published

2008

4. A Five-Year Climatology of Elevated Severe Convective Storms in the United States East of the Rocky Mountains.

Author

Horgan, Katherine L., Schultz, David M., Hales Jr., John E., Corfidi, Stephen F., and Johns, Robert H.

Subjects

*CLIMATOLOGY, *STORMS, *HAIL, *WINDS, *TORNADOES

Abstract

A 5-yr climatology of elevated severe convective storms was constructed for 1983–87 east of the Rocky Mountains. Potential cases were selected by finding severe storm reports on the cold side of surface fronts. Of the 1826 days during the 5-yr period, 1689 (91%) had surface fronts east of the Rockies. Of the 1689 days with surface fronts, 129 (8%) were associated with elevated severe storm cases. Of the 1066 severe storm reports associated with the 129 elevated severe storm cases, 624 (59%) were hail reports, 396 (37%) were wind reports, and 46 (4%) were tornado reports. A maximum of elevated severe storm cases occurred in May with a secondary maximum in September. Elevated severe storm cases vary geographically throughout the year, with a maximum over the south-central United States in winter to a central and eastern U.S. maximum in spring and summer. A diurnal maximum of elevated severe storm cases occurred at 2100 UTC, which coincided with the diurnal maximum of hail reports. The wind reports had a broad maximum during the daytime. Because the forecasting of hail from elevated storms typically does not pose as significant a forecast challenge as severe wind for forecasters and tornadoes from elevated storms are relatively uncommon, this study focuses on the occurrence of severe wind from elevated storms. Elevated severe storm cases that produce only severe wind reports occurred roughly 5 times a year. To examine the environments associated with cases that produced severe winds only, five cases were examined in more detail. Common elements among the five cases included elevated convective available potential energy, weak surface easterlies, and shallow near-surface stable layers (less than 100 hPa thick). [ABSTRACT FROM AUTHOR]

Published

2007