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Hurricane Principles Hurricane Isabel, 2003
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Outline Definitions Formation and Conditions Needed Growth and Structure of a Hurricane Where do They Form? Measurement Damage Forecasting
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What are hurricanes? Intense storm of tropical origin –Typhoon in North Pacific –Cyclone in India, Australia Winds sustained at 75+ mph ~80 form every year –Usually only few hit land/U.S. –Average ~30-40 fatalities/year
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Formation Requirements Shallow ocean water 80°F or more Warm humid air above water Weak upper level winds, blowing in direction of developing storm Timing: Summer, early Fall –Season in U.S. is June-November
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Stages of hurricane development
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Beginnings Low pressure with cluster of thunderstorms –Important for circulation –Tropical disturbance stage Thunderstorms grow, winds strengthen
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Rotation Surface winds converge, thunderstorms become more organized –Converge in CCW fashion due to Coriolis force –Only form ~5-20° latitude, not at equator (Coriolis force = 0)
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Strengthening Organization - means more warm moist air rising –Cools, releases massive amount of latent heat during condensation –Warms surrounding air, causes more updrafts, brings more air from below FUEL for more t-storms
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Into a Hurricane More fuel, more rotation, more speed Tropical storm: surface wind speeds between 39-74 mph Hurricane: surface winds sustained at 74+ mph –Also development of eye
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Eye of Hurricane Develops at ~74 mph wind speed –Why? Harder for rotating winds to reach surface Calm area, clear and cloud free –Why? Cold air sinking in eye, as descends, warms and absorbs moisture
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Eye Wall Cylinder of upward winds Strongest winds Heaviest precipitation
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Eye and Eyewall structure
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Conditions in Storm from West to East Approach: overcast sky, pressure begins to drop Towards eye: increasing wind speeds, huge waves (up to 30 ft), heavy rain In eye: air temperature increases, low wind, no rain, bright sky, lowest pressure East of eye: heavy rain, strong winds Move away from eye: pressure rises, winds and rain decrease
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Intensity Controlling factors: –Temperature of water –Release of latent heat –Why? Higher temperature water can drive more t-storms
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Duration of Storm Most last ~1 week Longer if they stay over warm water Shorter if they move over cold water or land Why? –Energy source gone –More friction for winds
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Where do they form? Not at equator (no Coriolis force) Subtropics ~5-20° latitude –Then move to higher latitudes –Path can vary based on details of high/low pressure systems it encounters Majority form SE Asia, India, Australia
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General origin points and paths of hurricanes/cyclones
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Origins of Atlantic Hurricanes
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Measuring Size Saffir-Simpson scale Based on wind speed, pressure –Expected storm surge, possible damage –Category 1-5
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Saffir-Simpson Scale
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Identification Names assigned at tropical storm strength Currently alternate male and female names alphabetically –System started in 1979 –6 lists are repeated –Names retired if storm is very costly/deadly Atlantic List 2005 Arlene Bret Cindy Dennis Emily Franklin Gert Harvey Irene Jose Katrina Lee Maria Nate Ophelia Philippe Rita Stan Tammy Vince Wilma
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Damage from Hurricanes High winds Storm surge Heavy rain Mudslides
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Winds Can be over 155 mph (Category 5) Impact can depend on which side of storm hits –Wind speed can be additive in direction of storm Can also generate large (10-15 m) waves that hit shorelines in advance of hurricane
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Wind damage in Florida - Andrew 1992
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Storm Surge Produce much of damage, fatalities Abnormal rise in water level of few meters
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Storm surge is a big problem for low-lying areas Deep water coastlines not as much of a problem
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Effects of storm surge on Florida coastline
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Storm Surge Why? –Eye is low pressure zone, local sea level rises –Winds near eye push water into mound, leads to big surge of water hit shore, move far inland Surge can be 20-30 ft –Think about New Orleans, much below sea level
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Heavy Rain After moving inland, no more water vapor to add fuel But there is a lot in the cloud already! –Will fall as rain –Can be significant (measured in ft) –Leads to flooding
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Downtown Houston after Tropical Storm Allison, 2001
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Mudslides Many examples of rain soaked hillslopes failing after hurricanes
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Forecasting: Seasonal General observations for Atlantic hurricanes More frequent if: –Wet summer in west Africa –Warmer sea temperatures –Low atmospheric pressure in Caribbean –No El Nino Weather phenomena of high level east-blowing winds in Pacific
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Why? West Africa wet summer: more t- storms, more hurricane potential Warm sea temps: more energy for storms Low pressure in Caribbean: requirement for storms No El Nino: weaker upper level winds (also condition for formation)
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General Path of Storms Probabilities of hurricanes hitting U.S. coastlines in any given year
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Short term prediction Location, movement, intensity closely monitored –Ship reports –Satellites –Radar –Buoys –Aircraft
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Warnings and Watches Watch: issued for large areas that might be affected –Usually issued a few days before landfall Warning: usually issued within 24 hours of storm striking area (+probability of striking) –Usually issued for large area (over 300 miles) to compensate for wide swath, variations in landfall
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Example of watches and warnings posted for Hurricane Erin, 1995
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Warnings and Watches Significantly reduced loss of life from hurricanes Not amount of damage
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Evacuation Can be a problem as more people move into coastal areas Evacuation time estimates for areas –72 hours New Orleans –50-60 hours Ft. Myers, FL –30-39 hours Miami –Problem: usually don’t have detailed knowledge of landfall during these periods
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Mitigating Damage Similar to earthquake planning Building codes –Withstand winds –Keep roofs on –Protecting windows Land use –Low-lying areas for parks, golf courses, not houses
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Next Time Hurricanes Part 2
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