Transcript Lecture 10
Lecture 10
Static Stability
General Concept An equilibrium state can be stable or unstable Stable equilibrium: A displacement induces a restoring force i.e., system tends to move back to its original state Unstable equilibrium: A displacement induces a force that tends to drive the system even further away from its original state
A More Realistic Scenario
Equilibrium
Small Displacement
Small Displacement
Small Displacement
Small Displacement
Small Displacement
Small Displacement
Small Displacement
Small Displacement
Small Displacement
Small Displacement
Small Displacement Stable.
Large Displacement
Large Displacement
Large Displacement
Large Displacement
Large Displacement
Large Displacement Unstable.
Idea of Previous Slides There may be a critical displacement magnitude displacement < critical stable displacement > critical unstable (More about this shortly)
Atmospheric Stability
Unsaturated Air
Consider a vertical parcel displacement, z Assume displacement is (dry) adiabatic Change in parcel temperature = d z Denote lapse rate of environment by
T=T 0 -
d
z
z T = T 0 z Temp of displaced parcel temp of environment
T = T 0
Parcel T = T 0 Environment
Two Cases Parcel temp. > environment temp. parcel less dense than environment parcel is buoyant Parcel temp. < environment temp.
parcel denser than environment parcel is negatively buoyant
Lapse Rates T parcel T env = T 0 = T 0 d z z T parcel > T > d env if T 0 d z > T 0 z T parcel < T < d env if T 0 d z < T 0 z
Stability > d resultant force is positive parcel acceleration is upward (away from original position) equilibrium is unstable < d resultant force is negative parcel acceleration is downward (toward original position) equilibrium is stable
z Graphical Depiction
Temp of rising parcel
Stable lapse rate Unstable lapse rate Temperature
Saturated Air Recall: Vertically displaced parcel cools/warms at smaller rate Call this the moist-adiabatic rate, m Previous analysis same with d by m Equilibrium stable if < m Equilibrium unstable if > m replaced
General Result Suppose we don’t know whether a layer of the atmosphere is saturated or not > d regardless > m equilibrium is unstable, Equilibrium is
absolutely unstable
< m regardless < d equilibrium is stable, Equilibrium is
absolutely stable
Continued Suppose m < < d Layer is stable if unsaturated, but unstable if saturated Equilibrium is
conditionally unstable
Absolutely stable
m
Conditionally unstable Absolutely unstable
d
Application If a layer is unstable and clouds form, they will likely be cumuliform If a layer is stable and clouds form, they will likely be stratiform
Example: Mid-Level Clouds Suppose that clouds form in the middle troposphere Unstable Stable altocumulus altostratus
Altocumulus
Altostratus
Deep Convection Previous discussion not sufficient to explain thunderstorm development Thunderstorms start in lower atmosphere, but extend high into the troposphere
Physics Review: Energy Object at height
h
h
Physics Review: Energy Remove support: Object falls
h
Physics Review: Energy Let z(t) = height a time t z(t)
It Can Be Shown … 1 2
m v
2
mgz
mgh
kinetic energy potential energy
(v = speed) As object falls, potential energy is converted to kinetic energy.
Available Potential Energy Object may have potential energy, but it may not be dynamically possible to release it
h Technically, PE = mgh, but lower energy state is inaccessible.
The energy is unavailable.
a
Energy Barriers To get from a to b, energy must be supplied to surmount the barrier. Energy needed: mgh b h b
h b
a h
Energy Barriers Now, ball can roll down hill.
b
Energy Barriers Amount of PE converted to KE: mg(h + h b ) Net release of energy: mg(h + h b ) – mgh b = mgh h b
a h b
CAPE, CIN CAPE: Convective Available Potential Energy (Positive area) CIN: Convective Inhibition (Negative area at bottom of sounding)
LCL Sounding Dry adiabat Saturated adiabat
Positive area Negative area
CAPE, CIN CIN is the energy barrier CAPE is the energy that is potentially available if the energy barrier can be surmounted
Isolated Severe Thunderstorms Suppose CIN and CAPE are large Consider a population of incipient thunderstorms Few of these storms will surmount the energy barrier, however … Those that do will have a lot of energy available.
Sudden Outbreaks of Severe Weather Start with a high energy barrier (large CIN)
Sudden Outbreaks of Severe Weather Now, suppose energy barrier decreases.
Sudden Outbreaks of Severe Weather Disturbances that previously couldn’t overcome the barrier now can.
If CAPE is large, storms could be severe.
Level of Free Convection (LFC) Level of Free Convection (LFC): When a parcel ceases to be colder and denser than surrounding air (environment), and instead becomes positively buoyant. On a thermo diagram, this occurs when the moist adiabat being followed by the parcel crosses from the cold side of the environmental profile to the warm side. The level at which this crossover occurs is the LFC.
Equilibrium Level (EL) Thermals will continue to rise until their temperature matches that of the environment. The level at which this occurs is called the equilibrium level (EL). Also called level of neutral buoyancy. At that point, parcels may overshoot a little, becoming colder than environment and ultimately falling back to their EL.
Convective Inhibition (CIN)
CIN
Z
0
LFC f B
(
z
)
dz
f B = Buoyancy force
f B
(
z
)
T
(
z
)
T
T
(
z
) (
z
)
g
T(z) temp of rising parcel, T’(z) temp of environment at same level.
CIN
g z
0
LFC
T
(
z
)
T
T
(
z
) (
z
)
dz
Buoyant force is negative by definition, minus sign in front of integral.
Convective Inhibition (CIN) Invoking hydrostatic approximation, and ideal gas law:
CIN
R d LFC
P
0
T
(
p
)
T
(
p
)
d
ln
p
CAPE
CIN
R d LFC P
0
T
(
p
)
T
(
p
)
d
ln
p
[J /kg] Once the parcel has overcome the energy barrier, CIN, and reached its LFC, CAPE is the energy that may be released by resulting buoyant ascent.
CAPE
R d EL
LFC
T
(
p
)
T
(
p
)
d
ln
p
[J /kg] CIN represents the energy barrier to initiation of free convection. CAPE is the maximum possible energy that can be released after CIN has been overcome.