ThermodynamicsM. D. Eastin Atmospheric Vertical Structure & Thunderstorms Forecast Question: Will a severe thunderstorm develop today? Or not? Having a.

Slides:

Advertisements

Similar presentations

Earth’s Weather Patterns

Advertisements

Thunderstorm Formation

BASIC UNDERSTANDING OF MESOSCALE DYNAMICS IN 0-6 HOUR TIMEFRAME Patrick Mukunguta Zimbabwe Meteorological Dept. Harare, Zimbabwe.

Stability and Severe Storms AOS 101 Discussion Sections 302 and 303.

Characteristics of Isolated Convective Storms

MesoscaleM. D. Eastin Deep Convection: Classification.

Thunderstorms. Thunderstorm Frequency See Figure in text.

Tornadoes, MCSs and Downbursts. Review of last lecture 1.The general size and lifetime of mesoscale convective systems, thunderstorms and tornadoes. 3.

1 FORMATION DES PREVISIONNISTES CONVECTION WEATHER FORECASTING IN MID-LATITUDE REGIONS IN MID-LATITUDE REGIONS Prepared in close collaboration with the.

20.3 Thunderstorms and tornadoes

Thunderstorms ASTR /GEOL Physics of Thunderstorms Two fundamental ideas: Convection Latent heat of vaporization/condensation.

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

Warm Up 3/4/08 True or False: The seasons are caused by changes in Earth’s distance from the sun. False Does land or water heat more rapidly? Land heats.

TROPOSPHERE The troposphere is the lowest layer of Earth's atmosphere. The troposphere starts at Earth's surface and goes up to a height of 7 to 20 km.

Stratosphere Troposphere

NATS 101 Lecture 2 Vertical Structure of the Atmosphere.

Thunderstorms. Review of last lecture 1.Two types of lightning (cloud-to-cloud 80%, cloud-to- ground 20%) 2.4 steps of lightning development. 3.How fast.

Unit 4 – Atmospheric Processes. Necessary Atmospheric Conditions 1. Water vapour must be available in the lower atmosphere to feed clouds and precipitation.

Severe Weather A SCIENTASTIC PRESENTATION. Storm Chaser’s Clip dominator.htm Discussion.

1. HAZARDS  Wind shear  Turbulence  Icing  Lightning  Hail 3.

Lecture 2a Severe Thunderstorm Primer Synoptic Laboratory II – Mesoscale Professor Tripoli.

Chapter 25 Modern Earth Science

Air, Weather, and Climate

Mesoscale convective systems. Review of last lecture 1.3 stages of supercell tornado formation. 1.Tornado outbreak (number>6) 2.Tornado damage: Enhanced.

Lesson 01 Atmospheric Structure n Composition, Extent & Vertical Division.

ThermodynamicsM. D. Eastin We just the covered the large-scale hydrostatic environment… We now need to understand whether a small-scale moist air parcel.

11.1 Atmospheric Basics atmosphere.

Nature of Storms Chapter 13.

Project Atmosphere American Meteorological Society Weather series: Thunderstorms.

National Weather Service Shreveport Working Together to Save Lives Understanding Severe Storms.

Barometric Pressure – The pressure due to the weight of the atmosphere.

The Nature of Storms There are 3 Stages of a thunderstorm:

Tropical Severe Local Storms Nicole Hartford. How do thunderstorms form?  Thunderstorms result from moist warm air that rises due to being less dense.

 The atmosphere is a layer of gases that are held in place by earths gravity – called air.  Atmosphere is 78% nitrogen and 21% oxygen.  The atmosphere.

THE ATMOSPHERE (chapter 24.1)

Chapter 10 Thunderstorms. Mid-latitude cyclone: counter-clockwise circulation around a low-pressure center Where are thunderstorms located? Along the.

Copyright © 2008 Pearson Education, Inc., publishing as Pearson Benjamin Cummings Central Case: Charging toward cleaner air in London London has had bad.

Introduction to Thermodynamic Diagrams

NATS 101 Lecture 1 Atmospheric Composition. 100 km a  6500 km C = 2  a  x 10 4 km Ratio: Height/ Length is 100/(4.084 x 10 4 )  2.45 x

1. The atmosphere 2 © Zanichelli editore 2015 Characteristics of the atmosphere 3 © Zanichelli editore 2015.

Weather Patterns. Weather Changes Because of the movement of air and moisture in the atmosphere weather constantly changes.

Phase of Water and Latent Heats

Troposphere About 75-80% of the atmosphere’s mass Rises to about 20km or about 7.5 miles Air is warmest at the bottom and gets colder as you move.

Layers of the Atmosphere

Chapter 15 The Atmosphere Mr. Manskopf Notes Also At

Warm up  Answer these questions in your notebook: 1. What is the difference between humidity and relative humidity? 2. What are clouds made of? 3. List.

Anatomy of a windy day. What keeps a cyclone or anticyclone going? Jet Streams Global Rivers of Air.

Thunderstorms (Tormenta) and Tornadoes After completing this section, students will discuss the formation of violent weather patterns such as thunderstorms.

Unit 6 Study guide Earth Space Science 6 th Grade CMS.

Weather Brain Pop Weather. What is Weather? Weather is the condition of Earth’s atmosphere from day to day. Earth’s atmosphere is the envelope of gases.

How to forecast the likelihood of thunderstorms!!!

ThermodynamicsM. D. Eastin We need to understand the environment around a moist air parcel in order to determine whether it will rise or sink through the.

Chapter 13.1 Thunderstorms

Characteristics of Isolated Convective Storms

Unit 5 Section 1 Thunderstorms

Severe Storms Classified under severe storms are thunderstorms, tornadoes, and hurricanes.

Understanding Severe Storms Thunderstorms.

The Atmosphere Layers and aerosols.

ATMOSPHERE AND WEATHER Essential Questions

Earth’s Atmosphere.

The Earth’s Warm Fuzzy Blanket

The Earth’s Warm Fuzzy Blanket

Weather & Climate Definitions

Weather and Climate Notes Part 1

The Layered Atmosphere:

6.1: Properties of the Atmosphere

Zimbabwe Meteorological Dept. Harare, Zimbabwe

Presentation transcript:

ThermodynamicsM. D. Eastin Atmospheric Vertical Structure & Thunderstorms Forecast Question: Will a severe thunderstorm develop today? Or not? Having a solid understanding of atmospheric thermodynamics helps forecasters answer this question every day…

ThermodynamicsM. D. Eastin Atmospheric Vertical Structure & Thunderstorms Outline:  Vertical Structure  Thunderstorms  Single Cell  Multicell  Supercell  Importance of Thermodynamics

ThermodynamicsM. D. Eastin Standard Atmosphere: The vertical variability of pressure and density is much larger than the horizontal and temporal variations of these quantities Earth’s atmosphere extends >150 km above sea level Half the mass of the atmosphere lies within the lowest ~6.0 km above mean sea level (MSL) 99% of the mass lies within the lowest 30 km above MSL Atmospheric Vertical Structure

ThermodynamicsM. D. Eastin Standard Atmosphere: Vertical distribution of temperature can be divided into four distinct layers The troposphere accounts for >80% of the mass, nearly all of the water vapor, clouds and precipitation in the Earth’s atmosphere Atmospheric Vertical Structure

ThermodynamicsM. D. Eastin Standard Atmosphere: Relatively little mixing occurs between the ozone rich stratospheric air and the moist, ozone-poor tropospheric air The troposphere and stratosphere together account for 99.9% of the atmospheric mass Atmospheric Vertical Structure

ThermodynamicsM. D. Eastin Standard Atmosphere: Mesosphere is the region where aurora borealis are sometimes observed Atmospheric Vertical Structure

ThermodynamicsM. D. Eastin Standard Atmosphere: Temperatures in the thermosphere are highly dependent on solar activity (e.g. sunspots and flares) and can reach very high values The International Space Station maintains a stable orbit within this atmospheric layer (at ~350 km) Atmospheric Vertical Structure

ThermodynamicsM. D. Eastin Standard Atmosphere: The changes in temperature with height are very important for driving vertical motions in the atmosphere Below the tropopause, pressure and density decrease with height more rapidly in cold layers than in warm layers We will soon learn why soon These differences between cold and warm layers are critical for the development of thunderstorms Atmospheric Vertical Structure

ThermodynamicsM. D. Eastin Why do forecasters worry about thunderstorms? Flash Floods Large Hail Strong winds Lightning Tornadoes Thunderstorms Change people’s daily plans Damage homes and towns Influence local economies

ThermodynamicsM. D. Eastin What are the important ingredients for thunderstorm development? Thunderstorms

ThermodynamicsM. D. Eastin Why do thunderstorms differ in size, shape, and longevity? Thunderstorms

ThermodynamicsM. D. Eastin Three Primary Types: 1.Single Cell (or “air mass”) 2. Multi-cell (e.g., squall lines) 3. Supercells Thunderstorms

ThermodynamicsM. D. Eastin Thunderstorms Single Cell Thunderstorms: Cumulus Stage (cloud dominated by updrafts) Mature Stage (both updrafts and downdrafts present) Dissipating stage (cloud dominated by downdrafts)

ThermodynamicsM. D. Eastin Thunderstorms Multi-Cell Thunderstorms: Composed of multiple single cells Updrafts and downdrafts work in concert to regularly develop new single cell storms on a preferred flank of the storm Warm updrafts rise rapidly Cold downdrafts act as a wedge forcing warm moist air upward

ThermodynamicsM. D. Eastin Thunderstorms Multi-Cell Thunderstorms: Warm air can rise spontaneously above certain levels Enormous quantities of moisture are condensed out of the air Modify the large-scale environment by transporting moisture and heat Often produce large hail and flash floods

ThermodynamicsM. D. Eastin Thunderstorms Supercell Thunderstorms: Strongest and most dangerous Large Hail Lightning Strong Tornadoes Single rotating updraft Two prominent downdrafts Occur when very warm air resides beneath very cold air

ThermodynamicsM. D. Eastin Thunderstorms Supercell Thunderstorms:

ThermodynamicsM. D. Eastin Thunderstorms Supercell Thunderstorms:

ThermodynamicsM. D. Eastin

ThermodynamicsM. D. Eastin Importance of Thermodynamics All thunderstorms are driven by strong updrafts and downdrafts The magnitude and location of all vertical motions are the result of vertical temperature differences All thunderstorms “condense out” large quantities of water vapor, producing clouds and precipitation All thunderstorms impact society, and they do so on a daily basis Successful forecasts of thunderstorms requires a solid understanding of atmospheric thermodynamics…

ThermodynamicsM. D. Eastin Atmospheric Vertical Structure & Thunderstorms Summary: Vertical Structure (variations in density, pressure, and temperature) Thunderstorms (produce severe weather and impact daily life) Single-cells Multi-cells Supercells Importance of Thermodynamics (critical to forecasts)

ThermodynamicsM. D. Eastin References Bluestein, H. B, 1993: Synoptic-Dynamic Meteorology in Midlatitudes. Volume II: Observations and Theory of Weather Systems. Oxford University Press, New York, 594 pp. Byers, H. R., and R. R. Braham, Jr., 1949: The Thunderstorm. Supt. Of Documents, U.S. Government Printing Office, Washington, D.C., 287 pp. Houze, R. A. Jr., 1993: Cloud Dynamics, Academic Press, New York, 573 pp. Lemon, L. R., and C. A. Doswell, 1979: Severe thunderstorm evolution and mesocyclone structure as related to tornadogenesis., Mon. Wea. Rev., 107, 1184–1197. Markowski, P. M., and Y. Richardson, 2010: Mesoscale Meteorology in Midlatitudes, Wiley Publishing, 397 pp. Petty, G. W., 2008: A First Course in Atmospheric Thermodynamics, Sundog Publishing, 336 pp. Tsonis, A. A., 2007: An Introduction to Atmospheric Thermodynamics, Cambridge Press, 197 pp. Wallace, J. M., and P. V. Hobbs, 1977: Atmospheric Science: An Introductory Survey, Academic Press, New York, 467 pp. Weisman, M. L., and J. B. Klemp, 1986: Characteristics of Isolated Convective Storms. Mesoscale Meteorology and Forecasting, Ed: Peter S. Ray, American Meteorological Society, Boston,