Northeast Convective Flash Floods: Helping Forecasters Stay Ahead of Rising Water Joe Villani - National Weather Service, Albany, NY Derek Mallia - University.

Slides:

Advertisements

Similar presentations

Forecasting Heavy Precipitation Associated with Cool-season 500-hPa Cutoff Cyclones in the Northeast Melissa Payer, Lance F. Bosart, Daniel Keyser Department.

Advertisements

Identifying key features to predict significant severe weather outbreaks in the northeastern U.S. Neil A. Stuart NOAA/NWS Albany NY NROW XIII 3 November.

WFO OKX – Topics in WDM Michael L. Ekster Severe Weather Warning Technology Workshop 12 July 2005.

Forecasting Distributions of Warm-Season Precipitation Associated with 500-hPa Cutoff Cyclones Matthew A. Scalora, Lance F. Bosart, Daniel Keyser Dept.

Matthew Vaughan, Brian Tang, and Lance Bosart Department of Atmospheric and Environmental Sciences University at Albany/SUNY Albany, NY NROW XV Nano-scale.

Flash Flood Composite Analysis in Vermont and Northern New York John M. Goff Gregory A. Hanson NWS Burlington, VT.

Analysis of Rare Northeast Flow Events By Joshua Beilman and Stephanie Acito.

 The main focus is investigating the dynamics resulting in synoptically forced training convective rainfall  Synoptic conditions necessary for the generation.

A Forecasting Success A negatively tilting mid level trough approaching North Carolina, combined with strong instability and increasing deep layer shear,

A Spatial Climatology of Convection in the Northeast U.S. John Murray and Brian A. Colle National Weather Service, WFO New York NY Stony Brook University,

Analysis of Precipitation Distributions Associated with Two Cool-Season Cutoff Cyclones Melissa Payer, Lance F. Bosart, Daniel Keyser Department of Atmospheric.

The Inland Extent of Lake Effect Snow (LES) Bands Joseph P. Villani NOAA/NWS Albany, NY Michael L. Jurewicz, Sr. NOAA/NWS Binghamton, NY Jason Krekeler.

Northeast Convective Flash Floods: Helping Forecasters Stay Ahead of Rising Water Joe Villani - National Weather Service, Albany, NY Derek Mallia - University.

A tale of two severe weather surprises – The isolated event of 16 July 2010 and the severe weather outbreak of 17 July 2010 Neil A. Stuart NOAA/NWS Albany,

Forecasting the Inland Extent of Lake-Effect Snow (LES) Bands: Application and Verification for Winter Joseph P. Villani NOAA/NWS Albany, NY.

Mike Evans NOAA/NWS Binghamton, NY Barry Lambert NOAA/NWS State College, Pa.

By Christopher Gitro NWS Binghamton, NY.  Flash flooding remains the number 1 weather killer across the US  29 flash flood related fatalities in BGM’s.

A Case Study of the August 25, 2007 Severe Weather Event in Eastern New York and Western New England Brian J. Frugis NWS WFO Albany, New York.

Kansas Severe Thunderstorm Outbreak May 7, 2002 Christopher Medjber Meteorology 503 Department of Geosciences SFSU Christopher Medjber Meteorology 503.

Warm-Season Lake-/Sea-Breeze Severe Weather in the Northeast Patrick H. Wilson, Lance F. Bosart, and Daniel Keyser Department of Earth and Atmospheric.

Case Studies of Warm Season Cutoff Cyclone Precipitation Distribution Jessica Najuch Department of Earth and Atmospheric Sciences University at Albany,

Warm-Season Lake-/Sea-Breeze Severe Weather in the Northeast Patrick H. Wilson, Lance F. Bosart, and Daniel Keyser Department of Earth and Atmospheric.

Meteorology 503 Meteorology 503 Tornadic Analysis Severe Weather Outbreak Dodge City, KS May 7, 2002 Julio C. Garcia! SFSU Julio C. Garcia! SFSU.

The Father’s Day 2002 Severe Weather Outbreak across New York and Western New England Thomas A. Wasula NOAA/NWS WFO at Albany.

The August 9, 2001 Lake Breeze Severe Weather Event Across New York and Western New England Thomas A. Wasula NOAA/NWS WFO at Albany.

The 8-9 March 2008 Winter Storm in Upstate New York: An Example of a “Multi- Hazard” Event Brian Frugis NOAA/NWS - Albany, NY NROW X November 5-6, 2008.

Case Studies of Warm Season Cutoff Cyclone Precipitation Distribution Jessica Najuch Department of Earth and Atmospheric Sciences University at Albany,

A Diagnostic Analysis of a Difficult- to-Forecast Cutoff Cyclone from the 2008 Warm Season Matthew A. Scalora, Lance F. Bosart, Daniel Keyser Department.

An Examination of the Tropical System – Induced Flooding in Central New York and Northeast Pennsylvania in 2004.

Cold Season 500 hPa Cutoff Cyclone Precipitation Distribution and a Case Study Tony Fracasso Department of Earth and Atmospheric Sciences University at.

A Storm-Scale Analysis of the 16 June 2008 Significant Severe Weather Event across New York and Western New England Thomas A. Wasula NOAA/NWS at Albany.

The 4 August 2004 Central Pennsylvania Severe Weather Event – Environmental and Topographical Influences on Storm Structure Evolution Joe Villani NOAA/NWS,

Characteristics of Isolated Convective Storms Meteorology 515/815 Spring 2006 Christopher Meherin.

Determining Favorable Days for Summertime Severe Convection in the Deep South Chad Entremont NWS Jackson, MS.

Use of TAMDAR Data in a Convective Weather Event Saturday, May 21, 2005.

Comparison of the 29−30 June 2012 and 11 July 2011 Derechos: Impact of the Appalachians Matthew S. Wunsch and Ross A. Lazear Department.

Christopher S. Foltz Jeremy Martin Brad Mickelson NWS WFO Goodland, KS 13 th High Plains Conference August 2009.

Mike Evans NWS / WFO BGM. CSTAR V – Severe convection in scenarios with low-predictive skill SUNY Albany researchers are examining SPC forecasts and associated.

Reanalysis of Southern New England Tornadoes To Improve Warning Verification Daniel Brook, Lyndon State College* Joseph DelliCarpini, NOAA/NWS Taunton,

National Weather Service Weather Forecast Office – Taunton, MA (BOX)

SYNOPTIC METEOROLOGY LABORATORY The Dallas and Fort Worth Storms of May 5, 1995 Storms of May 5, 1995 BY: Brent Crisp, Phil Grigsby, Thomas Jones, Devon.

A Study on the Environments Associated with Significant Tornadoes Occurring Within the Warm Sector versus Those Occurring Along Boundaries Jonathan Garner.

“Effects of Pacific Sea Surface Temperature (SST) Anomalies on the Climate of Southern South Carolina and Northern Coastal Georgia ” Whitney Albright Joseph.

Using The Short Fuse Composite to Forecast Severe Convection: Part II – “The Next Generation,” Updating the Technique By Jim Johnson & Mike Umscheid NWS.

Synoptic and Mesoscale Conditions associated with Persisting and Dissipating Mesoscale Convective Systems that Cross Lake Michigan Nicholas D. Metz and.

The Inland Extent of Lake- Effect Snow (LES) Bands Joe Villani NOAA/NWS Albany, NY Michael L. Jurewicz, Sr. NOAA/NWS Binghamton, NY Jason Krekeler State.

Henry Fuelberg Pete Saunders Pendleton, Oregon Research Region Map Types and Lightning Frequencies.

By Christopher Gitro NWS Binghamton, NY.  Flash flooding remains the number 1 weather killer across the US  29 flash flood related fatalities in BGM’s.

Composite Analysis of Environmental Conditions Favorable for Significant Tornadoes across Eastern Kansas Joshua M. Boustead, and Barbara E. Mayes NOAA/NWS.

An Examination of the Climatology and Environmental Characteristics of Flash Flooding in the Binghamton, New York County Warning Area Stephen Jessup M.S.

1 Heavy/Intense Precipitation Precipitation Intensity Precipitation Efficiency Precipitation Duration The precipitation part to the flood/flash flood problem.

Mike Evans NWS Binghamton, NY. Outline The checklist Example – April 28, 2011 Verification Summary / Conclusion.

A “Survey” of Tornadoes and their Environments in the WFO Sterling, VA Forecast Area Matthew R. Kramar Senior Forecaster, WFO LWX Kyle M. Olmstead Student.

CONVECTIVE STORM STRUCTURES AND AMBIENT CONDITIONS ASSOCIATED WITH SEVERE WEATHER OVER THE NORTHEAST UNITED STATES Kelly A. Lombardo and Brian A. Colle.

Analyzing the Roles of Low-Level Forcing and Instability in Significant Severe Weather Outbreaks in the Eastern United States Neil A. Stuart NOAA/NWS Albany.

An Examination of “Parallel” and “Transition” Severe Weather/Flash Flood Events Kyle J. Pallozzi and Lance F. Bosart Department of Atmospheric and Environmental.

 Hydrometeorological Aspects of the Kansas Turnpike Flash Flood of August Authors: Jeffrey D. Vitale James T. Moore Charles E. Graves, Matt.

The July 19, 2015 “Non Severe” Event in Southern New England What Happened? NROW XVI – November, 2015 Frank Nocera NOAA/NWS Taunton MA.

A Case Study of Two Left-Moving Mesoanticyclonic Supercells on 24 April 2006 Chris Bowman National Weather Service – Wichita, KS.

A Rare Severe Weather and Tornado Event in Central New York and Northeast Pennsylvania: July 8, 2014 Presented by Mike Evans 1.

AN INDEX FOR ANTICIPATING EXCESSIVE PRECIPITATION WITH ELEVATED THUNDERSTORMS Alzina Foscato and Patrick Market Dept. of Soil, Environmental & Atmospheric.

OKX The OKX sounding at 1200 UTC has 153 J kg -1 CIN extending upwards to 800 hPa and < 500 J kg -1 CAPE. There was 41.8 mm of precipitable water. By 1400.

Heavy Rain Climatology of Upper Michigan Jonathan Banitt National Weather Service Marquette MI.

Alan F. Srock and Lance F. Bosart

Warm Season Flash Flood Detection Performance at WFO Binghamton

Case Studies of Warm Season Cutoff Cyclone Precipitation Distribution

VERIFICATION – DAY CLD: 6.5/10.

William Flamholtz, Brian Tang, and Lance Bosart

28-29 July 2013 Philadelphia Heavy Rainfall Event

Brian J. Frugis and Thomas A. Wasula NOAA/NWS Albany, New York

Presentation transcript:

Northeast Convective Flash Floods: Helping Forecasters Stay Ahead of Rising Water Joe Villani - National Weather Service, Albany, NY Derek Mallia - University at Albany ER Flash Flood Conference – June 2-4, 2010

Goals Better anticipate meteorological environments that produce flash flooding (FF) Forecast “watch” phase of a FF event (12-24 hours in advance) Identify factors that may distinguish days with isolated vs. widespread FF

Methodology Investigated 39 FF events from Albany County Warning Area (CWA) Warm season events from 2003 through 2009 (non-tropical) Classified events based on type of dominant feature when FF occurred

Methodology Compiled sounding derived parameters for each event Entered data in spreadsheet Stratified data based on isolated vs. widespread events

Methodology Isolated = FF occurring over a small area resulting from one cluster of convection Widespread = FF occurring over a large (or multiple) area(s) resulting from several clusters of convection

Methodology Composite plots of synoptic scale features using CDC website Compared composites for days with widespread vs. isolated FF Signatures evident in: –500 hPa height anomalies –850 hPa meridional wind anomaly –250 hPa zonal wind mean

Data Sources Weather Event Simulator (WES) –Archived local AWIPS data Radar, satellite, surface observations, observed soundings, model initialized soundings Soundings from 12 UTC or 18 UTC –Times preceded FF occurrences –Data mainly from ALB, some OKX

Sounding Derived Indices Averages for all FF events CAPE 938 J/Kg K-Index 33 PWAT 1.68” Freezing level 13,200 ft Max wind 0-3 km 17 kt

Significant Features Four different classifications: 1.Cut-off Low 2.Frontal (cold, warm, stationary) 3.Upper Level Ridge/Surface boundary 4.Upper Level Trough/Low (NOT cut-off)

Widespread vs. Isolated FF Comparison ParameterIsolatedWidespread Avg # reports37 Sig featureFrontalCut-off Low CAPE1046 J/Kg823 J/kg K-Index3234 PWAT Freezing level12,900 ft13,600 ft Max 0-3 km Wind 15 kt19 kt

Widespread vs. Isolated FF Comparison Not much difference in parameters overall –Somewhat stronger max 0-3 km wind –Other parameters relatively insignificant Signatures evident in composites plots of synoptic scale features

Widespread vs. Isolated FF Comparison 250 hPa Zonal Wind Mean Right Entrance Region of Jet

Widespread vs. Isolated FF Comparison 250 hPa Zonal Wind Mean: –Northeast CONUS in pronounced right-entrance region of jet (widespread) –Jet displaced farther north and east and weaker (isolated)

Widespread vs. Isolated FF Comparison 500 hPa Geopotential Height Anomaly Stronger Negative Height Anomaly Weaker Negative Height Anomaly

Widespread vs. Isolated FF Comparison 500 hPa Geopotential Height Anomaly: –Much stronger negative anomaly across Great Lakes and Midwest regions (widespread) –Stronger positive anomaly across Canadian Maritimes, Hudson’s Bay and Pacific NW (widespread)

Widespread vs. Isolated FF Comparison 850 hPa Meridional Wind Anomaly Stronger Meridional Wind Anomaly Weaker Meridional Wind Anomaly

Widespread vs. Isolated FF Comparison 850 hPa Meridional Wind Anomaly: –Stronger and more expansive positive anomaly (southerly wind component) across Eastern New York into New England (widespread)

Observations/Conclusions Widespread FF more likely with Cut-off Lows –8 of 12 Cut-off Low events resulted in widespread FF Most events occurred in June/July and during the afternoon and evening hours

Observations/Conclusions ( From Sounding Data) Most events exhibited veering wind profile in lowest 3 km –Less directional shear for widespread events Mainly unidirectional flow 3-6 km “Tall/Skinny” character of CAPE for most events

Observations/Conclusions Surface dewpoints in the 60s-70s for all events except one –June 15th 2009 dewpoints in the 50s Almost all cases exhibited positive Theta-E advection at 850 hPa

Observations/Conclusions (Storm Scale) FF producing cells were either: 1.Low Echo Centroids – most of significant reflectivity below 0°C level (warm cloud processes resulting in high efficiency rainfall) 2.Slow-moving cells with taller updrafts (some produced hail and FF) 3.Training cells (repeatedly moved across the same areas)

Example of LEC 0°C level

Observations/Conclusions Freezing level and PWAT may be a good indicator FF in general: –Average FZL = 13,200 ft –Average PWAT = 1.68” However, they do NOT distinguish between isolated/widespread events

Future Work Look for synoptic features (from composites) when forecasting isolated vs. widespread FF Develop updated FF checklist for staff at Albany Investigate hydrologic component of FF?

Acknowledgments Derek Mallia, University at Albany Julie Gabriel, University of Delaware Neil Stuart, NWS Albany

Questions? Courtesy: Brian Frugis