Advanced Synoptic M. D. Eastin

Jet Streams and Jet Streaks

Advanced Synoptic M. D. Eastin

Jet Streams

• Definition and Basic Characteristics• Basic Forcing Mechanism• Common Jets in the Mid-latitudes

Jet Streaks

• Definition and Basic Characteristics• Vertical Motion Pattern• Coupling with Surface Fronts• Relationship to Severe Weather

Jet Streams and Jet Streaks

Advanced Synoptic M. D. Eastin

Jet StreamsBasic Characteristics:

• Long narrow band of strong winds

• ~500-6000 km in length• ~100-400 km in width• Not a continuous band• Maximum winds ~50-250 knots• Can be located at any altitude• Common mid-latitude types include the polar, subtropical, and low-level jets

• Migrate and evolve over times scales from a few hours to seasonally

• Primarily influence the motion and evolution of synoptic-scale systems• Contribute to the initiation and evolution of mesoscale systems and deep convection

Advanced Synoptic M. D. Eastin

Jet StreamsBasic Forcing Mechanism:

All jets are a response to flow down strong large-scale pressure gradients (produced by temperature gradients) that is then turned by the Coriolis force

All long-lived jets are in thermal wind balance

y

T

pf

R

p

udg

J Mean ZonalWind

MeanTemperature

J

Maximum N-STemperature and

Pressure Gradient

H LPGF

Equator

North Pole

H

L

PGF

Coriolis forceturns wind

Jet

Advanced Synoptic M. D. Eastin

Jet StreamsBasic Forcing Mechanism: Thermal Wind Balance

Notice how all of the strong upper-level jets (at 300 mb) are located directly above a strong low-level temperature gradient (at 850 mb)

Advanced Synoptic M. D. Eastin

Common Jet StreamsPolar-Front Jet (PFJ):

• Often located near 300 mb just below the mid-latitude tropopause• Winds are westerly (blow west to east) and often exceed 75 m/s

• Associated with strong quasi-horizontal temperature gradients at low-levels (Note: Jet migration is a response to the strong temperature gradient moving)

• Present year round

• Furthest north (~50ºN) and weakest during the summer months

• Furthest south (~35ºN) and strongest during the winter months

• Most deep convection develops equatorward of the polar jet

Isentropic Mean Meridional Cross Section

Advanced Synoptic M. D. Eastin

Common Jet StreamsSubtropical Jet (STJ):

• Often located near 200 mb just below the tropical tropopause• Winds are westerly but rarely exceed 50 m/s

• Associated with a moderate quasi-horizontal temperature gradients at mid-levels • Primarily a wintertime phenomenon

• Meanders between 20ºN and 35ºN

• Often is oriented from the southwest to the northeast across the Pacific and southern or western U.S. (“pineapple express”)

• Most deep convection develops poleward of the subtropical jet

Isentropic Mean Meridional Cross Section

Advanced Synoptic M. D. Eastin

Common Jet StreamsSubtropical Jet (STJ):

• Often very difficult to distinguish from the polar jet on daily weather maps

• Since the subtropical jet is located further south (where f is smaller), a strong jet can still develop from a moderate temperature gradient

• Let’s do a simple analysis assuming

the following are held constant:

∂p ~ 800 mb p ~ 500 mb Rd ~ 300 J/kg/K ∂y ~ 1000 km

Polar-Front Jet

Subtropical Jet

Polar Jet: Φ ~ 40ºN ∂T ~ 20 K

Subtropical Jet: Φ ~ 20ºN ∂T ~ 10 K

∂ug ~ 98 m/s

∂ug ~ 92 m/s

y

T

pf

R

p

udg

Advanced Synoptic M. D. Eastin

Common Jet StreamsLow-level Jets (LLJ):

• Located 500-2000 m AGL• Winds rarely exceed 25 m/s

• Associated with weak horizontal temperature gradients confined to lower levels

• Can occur year round

1. Pre-frontal LLJ:

• Located just ahead (east) of strong cold fronts

• Responsible for the rapid advection of warm moist air that can help “feed” deep convection along the front

ColdAir

WarmAir

LLJ

WarmAir

ColdAir

J

Advanced Synoptic M. D. Eastin

Common Jet Streams2. Nocturnal LLJ:

• Primarily oriented north-south• Maximum intensity at night in the

summer

• Increased nocturnal thunderstorm activity

is partially a result of the LLJ providing a continuous supply of warm, moist air to the storm cloud bases

• Intensity fluctuations are linked to diurnal

changes in the low-level temperature gradients along the gradually sloping (east-west) topography

Nocturnal Boundary Layer – Radiational Cooling

WarmAirJ

LLJ

East-West Cross Section 9 June 2002 at 12ZPotential temperature (red contours)

Wind speed (shading)

Advanced Synoptic M. D. Eastin

Jet StreaksBasic Characteristics:

• Faster moving “pockets” of air embedded within the jet stream• ~250-1000 km in length• ~50-200 km in width

• Migrate and evolve over times scales from a few hours to a few days• Motion is often much slower than the speed of the wind within the jet stream or streak

• Primarily influence the initiation and evolution of mesoscale systems and deep convection

• Contribute to the evolution of synoptic-scale systems since most contain strong PVA

Jet Stre

am

Jet Streaks

Advanced Synoptic M. D. Eastin

Physical Interpretation of the Basic Pattern:

• Using a simplified vorticity equation:

• Thus, the vorticity change experienced by an air parcel moving through the jet streak:

Vorticity decrease → Divergence aloft→ Upward motion

Vorticity increase → Convergence aloft→ Downward motion

Recall: QG theory provides an alternativeexplanation (with the same result)

Divergence / convergence patterns result from ageostrophic motions

y

v

Dt

D

x

u +

_VortMin

VortMax

JET

VorticityDecrease

VorticityIncrease

VorticityIncrease

VorticityDecrease

JET

Descent

AscentDescent

Ascent

LeftExit

LeftExit

RightExit

RightExit

LeftEntrance

LeftEntrance

RightEntrance

RightEntrance

Jet Streak Vertical Motions

VorticityChange

Divergence

Advanced Synoptic M. D. Eastin

An Example:

Jet Streak Vertical Motions

Divergence = yellow contoursRegions of expected upward vertical

motion

Advanced Synoptic M. D. Eastin

An Example:

Jet Streak Vertical Motions

Important Considerations!!!

1. Forcing is at upper-levels2. Forcing is on the synoptic scale3. Is there a mechanism for low-level lift?4. Is the low-level environment moist?

Advanced Synoptic M. D. Eastin

Coupling between Jet Streaks and Fronts The orientation of a surface front and an upper-level jet streak can lead to either enhanced (deep) convection or suppressed (shallow) convection along the front

Enhanced Convection → Left exit or right entrance region is above the front → Helps destabilize the potentially unstable low-level air

→ Increases the likelihood of deep convection

Advanced Synoptic M. D. Eastin

The orientation of a surface front and an upper-level jet streak can lead to either enhanced (deep) convection or suppressed (shallow) convection along the front

Suppressed Convection → Left entrance or right exit region is above the front → Prevents destabilization of the potentially unstable air

→ Decreases the likelihood of deep convection

Coupling between Jet Streaks and Fronts

Advanced Synoptic M. D. Eastin

The orientation of a surface front , an upper-level jet streak, and a low-level jet streak can further enhance deep convection along the front

More Enhanced Convection → A “favorable” combination of ageostrophic circulations from each jet streak and the front can create strong

lift along the warm (unstable) side of the front → Often the location of the most severe deep convection

Coupling between Jet Streaks and Fronts

Advanced Synoptic M. D. Eastin

Is severe weather often associated with jet streaks?

• Recent climatology conducted by Clark et al. (2009)• Examined the location all severe weather reports (tornado, hail, winds) relative to any upper-level jet streaks during the warm season (March-September) of 1994-2004

Expectations:

• Most severe weather is associated with jet streaks → Increased vertical shear

→ Enhanced storm longevity

• More severe weather in the right entrance and left-exit regions→ Enhanced vertical motion→ Greater likelihood of surface parcels being lifted to LFC→ Greater near-surface moisture convergence

Jet Streaks and Severe Weather

Advanced Synoptic M. D. Eastin

Answer: Yes - severe weather is regularly associated with jet streaks

Results:

• A total of 126,864 storm reports occurred during the period of study• 84% were associated with an upper-level jet streak.

Jet Streaks and Severe Weather

Advanced Synoptic M. D. Eastin

Where is the severe weather located?

Results:

• Majority of reports are located in the right-entrance region and along the jet streak axis in the exit region

Jet Streaks and Severe Weather

Left Entrance

Right Entrance

LeftExit

RightExit

Advanced Synoptic M. D. Eastin

Composite Structure:

Jet Streaks and Severe Weather

Advanced Synoptic M. D. Eastin

Composite Structure:

Jet Streaks and Severe Weather

Advanced Synoptic M. D. Eastin

ReferencesBeebe, R. G., and F. C. Bates, 1955: A mechanism for the assisting in the release of convective instability. Mon. Wea.

Rev., 83, 1-10.

Bluestein, H. B., 1986: Fronts and jet streaks: A theoretical perspective. Mesoscale Meteorology and Forecasting, Amer. Meteor. Soc., Boston, 173-215.

Bluestein, H. B., 1993: Synoptic-Dynamic Meteorology in Midlatitudes. Volume II: Observations and Theory of WeatherSystems. Oxford University Press, New York, 594 pp.

Bonner, W. D., 1968: Climatology of the low level jet. Mon. Wea. Rev., 96, 833-850.

Browning, K. A., and C. W. Pardoe, 1973: Structure of low-level jet stream ahead of mid-latitude cold fronts. Quart. J. Roy.Meteor. Soc., 99, 619-638.

Clark, A. J., C. J. Schaffer, W. A. Gallus, and K. Johnson-Omara, 2009: Climatology of storm reports relative to upper-level jet streaks. Wea. Forecasting, 24, 1032-1051.

Keyser, D., M. J. Reeder, and R. J. Reed, 1988: A generalization of Pettersen’s frontogenesis function and its relation to

the forcing of vertical motion. Mon. Wea. Rev., 116, 762-780.

Krisnamurti, T. N., 1961: The subtropical jet stream in winter. J. Meteor., 18, 172-191.

Murray, R., and S. M. Daniels, 1953: Transverse flow at the entrance and exit to jet streams. Quart. J. Roy. Meteor. Soc.,99, 619-638.

Pyle, M. E., D. Keyser, and L. F. Bosart, 2004: A diagnostic study of jet streaks: Kinematic signatures and relationship tocoherent tropopause disturbances. Mon. Wea. Rev., 132, 297-319.

Uccellini, L. W., and D. J. Johnson, 1979: The coupling of upper and lower tropospheric jets streaks and implications forthe development of severe convective storms. Mon. Wea. Rev., 107, 682-703.