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AN INTRODUCTION TO SEVERE WEATHER

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EHI below 1.0:Supercells and tornadoes unlikely in most cases, ... EHI over 4.0: Violent mesocyclone-induced tornadoes (F4 and F5) possible. ... – PowerPoint PPT presentation

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Title: AN INTRODUCTION TO SEVERE WEATHER


1
AN INTRODUCTION TO SEVERE WEATHER
2
TOPICS
  • Types of Thunderstorms
  • Severe Weather Indices
  • Severe Soundings
  • Hodographs
  • Basic Severe Radar

3
Thunderstorm Ingredients
  • Moisture
  • Instability
  • Shear
  • Forcing (Lifting) Mechanism

4
Stages of Development
5
(No Transcript)
6
Single Cell or Pulse
  • Single-Cell Storms
  • Moves with mean environmental wind over 5-7 km.
  • 30- 60 minute duration.
  • Rainfall can be moderate to heavy, small hail is
    possible.
  • Vertical wind shear is small.
  • Form in very weak shear environments with new
    storms forming in an unorganized manner
  • Can be severe at dissipation

7
Pulse Storm Lifespan
8
Multi Cell Clusters
  • Cluster of 2-4 storms
  • Feed off gust front
  • Moderate unidirectional shear and med to large
    CAPE
  • Follow mean 700 500 mb flow

9
Mesoscale Convective Complex
  • May Aug (86)
  • Multi celled storms gone wild
  • Oval shaped O.7 axis of eccentricity
  • Cloud shield 50,000 km2
  • Last at least 6 hours
  • Usually night events
  • Flash floods
  • Hail

10
Squall Lines
  • Linear multi cell storms
  • Frontal or pre-frontal
  • Vertical tilt increases severity
  • Moist low level S or SE inflow
  • Mid level flow 25 knots and - to low level flow

11
Squall Line Lifespan
12
BOW ECHOS and DERECHOS
  • Nasty Squall Line
  • Strong downbursts
  • Mid level winds are forced to the surface
  • Axis 400 km
  • Large area of winds 58mph
  • Progressive
  • Serial
  • Bow Echoes

13
Supercells
  • 3 basic types
  • LP
  • Classic
  • HP
  • Rotating updraft
  • Usually evolves from non severe strom
  • Higher cape and higher shear more severe

14
LP
  • Updraft dominated
  • Translucent precip core
  • Outflow deficient
  • Some large hail
  • Very picturesque
  • Dry Line

15
HP
  • Typical of eastern U.S.
  • Most common
  • Strong downdrafts
  • Shapes can be undefined
  • High reflectivity hooks on radar

16
Classic
  • Balanced updraft and downdraft
  • Rear flank downdraft is stronger than LP
  • Low level mesocyclogenesis more likely
  • Moderate hook echo
  • Nados are common

17
CINH The Cap and CAPE
  • What is CINH?CINH (Convective Inhibition in
    units of Joules per kilogram) is anti-CAPE
    (negative CAPE) in the lower troposphere.
  • This is the region where a parcel of air if
    raised from the lower PBL would sink back down
    again.
  • Anti Cape
  • CINH
  • 0 - 50 Weak Cap
  • 51 - 199 Moderate Cap
  • 200 Strong Cap
  • CAPE
  • 1 - 1,500 Positive
  • 1,500 - 2,500 Large
  • 2,500 Extreme

18
Lifted Index
  • LI (Lifted Index) is an index used to assess low
    level parcel (in)stability of the troposphere.
  • LI formula Temperature of Environment at 500 mb
    - Parcel temperature at 500 mb
  • If the LI is -6.2 the parcel of air raised from
    50 mb above the surface to the 500 mb level will
    be 6.2 degrees warmer (positively buoyant) as
    compared to the 500 mb actual (environmental)
    temperature.
  • LIFTED INDEX
  • Positive number Stable
  • 0 to -4 Marginal instability
  • -4 to -7 Large instability
  • -8 or less Extreme instability

19
Showalter Index
  • The SI (Showalter Index) is an index used to
    assess 850 mb parcel (in)stability.
  • SI formula Temperature of Environment at 500 mb
    - Parcel temperature at 500 mb (raised from 850
    mb)
  • SHOWALTER INDEX
  • Positive number Stable
  • 0 to -4 Marginal instability
  • -4 to -7 Large instability
  • -8 or less Extreme instability

20
KI
  • The KI (K INDEX) is an index used to assess
    convective potential.
  • The KI is a combination of the Vertical Totals
    (VT) and lower tropospheric moisture
    characteristics. The VT is the temperature
    difference between 850 and 500 mb while the
    moisture parameters are the 850 mb dewpoint and
    700 mb dewpoint depression.KI (T850 - T500)
    (Td850 - Tdd700)
  • K INDEX
  • 15-25 Small convective potential
  • 26-39 Moderate convective potential
  • 40 High convective potential

21
Total Totals
  • The TT (Total Totals) is an index used to assess
    storm strength.
  • The TT is a combination of the Vertical Totals
    (VT) and Cross Totals (CT). The VT is the
    temperature difference between 850 and 500 mb
    while the CT is 850 mb dewpoint minus the 500 mb
    temperature.TT (T850 - T500) (Td850 - T500)
  • TOTAL TOTALS
  • 44-50 Likely thunderstorms
  • 51-52 Isolated severe storms
  • 53-56 Widely scattered severe
  • 56 Scattered severe storms

22
SWEAT
  • SW (SWEAT Severe Weather Threat Index) uses
    several variables to determine the likeliness of
    severe weather and tornadoes.
  • SWEAT 12(850Td) 20(TT - 49) 2(V850) (V500)
    125(sin(dd500 - dd850) 0.2)If TT less than
    49, then that term of the equation is set to zero
    If any term is negative then that term is set
    to zeroWinds must be veering with height or
    that term is set to zero850Td 850 mb dewpoint
    temperatureTT Total Totals IndexV850 850 mb
    wind speedV500 500 mb wind speeddd500 - dd850
    Directional veering of wind with height
  • SWEAT
  • 150-300 Slight severe
  • 300-400 Severe possible
  • 400 Tornadic possible

23
Helicity
  • Helicity (HEL) is a mathematical quantity derived
    from speed shear and directional shear and the
    strength of the low level wind directly into the
    speed and directional wind shear.
  • HELICITY
  • 150-300 Possible supercell
  • 300-400 Supercells favorable
  • 400 Tornadic possible

24
Energy Helicity Index
  • The Energy Helicity Index (EHI) is a combination
    of two indices.
  • CAPE and SR Helicity.
  • EHI (CAPE SR HEL) / 160,000
  • EHI below 1.0Supercells and tornadoes unlikely
    in most cases,
  • EHI  1.0 to 2.0Supercells and tornadoes are
    possible but usually tornadoes are not violent or
    long-lived.
  • EHI  2.0 to 2.4Supercells more likely and
    mesocyclone-induced tornadoes possible.   
  • EHI  2.5 to 2.9Mesocyclone-induced
    supercellular tornadoes more likely.
  • EHI  3.0 to 3.9Strong mesocyclone-induced
    tornadoes (F2 and F3) possible.
  • EHI over 4.0 Violent mesocyclone-induced
    tornadoes (F4 and F5) possible.

25
Bulk Richardson Number (BRN)
  • BRN (Bulk Richardson Number) is an index that
    assesses the balance between instability (CAPE)
    and wind shear (speed and directional shear with
    height) in a thunderstorm environment.
  • The basic formula is CAPE / SHEAR. BRN CAPE /
    (0.5(shear differential)2)
  • CAPE determines the updraft strength while the
    SHEAR determines storm character (supercell, MCS,
    pulse).
  • Multi-cell storms (MCS) are favored in cases
    where good speed SHEAR is present but low level
    directional shear is weak.
  • Pulse storms are favorable in cases with high
    CAPE and low shear.
  • Supercells are favored when CAPE and SHEAR are in
    balance and both are significant.
  • BRN
  • 45 CAPE much higher than SHEAR- often pulse
    storms if CAPE is weak to moderate
  • Teens Optimum for supercells

26
BRN Shear
  • BRN shear may be more useful than BRN in
    differentiating tornado environments
  • BRN shear 0.5 (Uavg)2
  • in m2/s2, where Uavg, the magnitude difference
    between the 0-6 km mean wind in the lowest 0.5
    km, is squared
  • BRN shear 25 to 100 Associated with tornadic
    supercells

27
Deep Convective Index (DCI)
  • The DCI attempts to combine the properties of
    equivalent potential temperature (Qe) at 850 mb
    with instability.DCI T(850 mb) Td(850 mb) -
    LI(sfc-500 mb)in degrees C, where LI represents
    the lifted index value from the surface to 500
    mb.
  • DCI values of roughly 30 or higher indicate the
    potential for strong thunderstorms.

28
Wet Bulb Zero (WBZ)
  • Wet bulb temperature (Tw) represents the lowest
    temperature a volume of air at a constant
    pressure can be cooled to by evaporating water
    into it.
  • Its value falls between the dry bulb (actual air)
    temperature and dewpoint.
  • The height of the wet bulb zero is that level on
    the sounding whereby the lowest temperature
    attainable is zero degrees C, i.e. Tw 0 C at
    this level.
  • In general, WBZ heights from 5,000 to 12,000 ft
    AGL are associated with hail at the ground.
  • The potential for large hail is highest for WBZ
    heights of 7,000 to 10,000 ft AGL, with rapidly
    diminishing hail size below 6,000 and above
    11,000 ft AGL.

29
Inverted V (Dry Microburst)
  • Named Inverted-V since the dewpoint depression
    decreases significantly with height
  • High based convection from high CCL

30
Wet Microburst
  • Mid-level dry air
  • Similar to goal post sounding but with more
    moisture (higher precipitable water in sounding)
  • The dry air aloft will entrain into the downdraft
    and cause evaporational cooling.
  • This increases the negative buoyancy and can
    result in microbursts

31
Goalpost (Loaded Gun)
  • Severe weather sounding (large CAPE, very
    unstable LI) (mT air in boundary layer capped by
    cT air)
  • There must be an inversion above mT air
  • If speed /directional wind shear and strong
    low-level jet are present on sounding, severe
    weather chances are enhanced

32
Basic Hodograph
  • The primary purpose of a hodograph is to reveal
    vertical wind shear
  • Vertical wind shear is a description of how the
    velocity of the horizontal wind changes with
    height.
  • The hodograph is based on wind vectors, rather
    than wind barbs.
  • The total magnitude of vertical wind shear over a
    particular depth is an important factor in
    anticipating possible storm structure and
    evolution.

33
Severe WX Types
34
Severe Wx Types
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