chapter 6

Question 1

A flow is hydrodynamically unstable if

Answer 1

a small perturbation in the flow grows spontaneously, drawing energy from the mean flow.

Question 2

It is useful to divide fluid instabilities into two types:

Answer 2

parcel instability and wave instability

Question 3

Examples of parcel instability are

Answer 3

buoyant instability and inertial instability.

Question 4

Buoyant Instability

Answer 4

If the atmospheric lapse rate (Γ) is more than the dry adiabatic lapse rate (Γ􏰥), an air parcel displaced upward will become buoyant and tend to move away from to its original level.

Question 5

Inertial Instability

Answer 5

If an air parcel that is moving with the zonally directed geostrophic basic flow, is displaced across the stream, will accelerate further from that position

Question 6

In buoyant and inerital instability an air parcel moved from its original position will

Answer 6

continue to accelerate away from where it started, instead of oscillating around its original position.

Question 7

Most of the instabilities of importance in meteorology, are associated with

Answer 7

wave propagation

Question 8

The wave instabilities important for synoptic-scale meteorology generally occur in the form of

Answer 8

perturbations to a zonally symmetric basic flow field

Question 9

A

Answer 9

Question 10

B

Answer 10

Question 11

C

Answer 11

Question 12

D

Answer 12

Question 13

In general the basic flow is

Answer 13

a jetstream that has both horizontal and vertical mean-flow shears.

Question 14

Examples of wave instability are:

Answer 14

barotropic and baroclinic instability.

Question 15

Barotropic Instability is

Answer 15

a wave instability associated with the horizontal shear in a jet-like current.

Question 16

Barotropic instabilities grow by

Answer 16

extracting kinetic energy from the mean-flow

Question 17

Baroclinic instability, is associated with

Answer 17

vertical shear of the mean flow.

Question 18

Baroclinic instabilities grow by

Answer 18

converting potential energy associated with the mean horizontal temperature gradient that must exist to provide thermal wind balance for the vertical shear in the basic state flow.

Question 19

Wave Instability Assessment

Step 1:

Answer 19

Question 20

Wave Instability Assessment

Step 2:

Answer 20

Question 21

Wave Instability Assessment

Step 3:

Answer 21

Question 22

Wave Instability Assessment

Step 4:

Answer 22

Question 23

If N is real then the fluid is

Answer 23

stable, and a parcel disturbed vertically from rest would oscillate about its original position.

Question 24

If N is real then the fluid is stable, and a parcel disturbed vertically from rest would oscillate about its original position. However, if N is imaginary then

Answer 24

we know a parcel will be unstable

Question 25

If N is real then the fluid is stable, and a parcel disturbed vertically from rest would oscillate about its original position. However, if N is imaginary then we know a parcel will be unstable, and if perturbed from rest it will

Answer 25

accelerate away from its original position.

Question 26

If N is real then the fluid is stable, and a parcel disturbed vertically from rest would oscillate about its original position. However, if N is imaginary then we know a parcel will be unstable, and if perturbed from rest it will accelerate away from its original position.

This can also be seen from

Answer 26

the dispersion relation, since N will be imaginary, and hence w will have an imaginary component.

Question 27

One form of ………………………………… that can occur in the atmosphere is barotropic instability, associated with ……………………………………

Answer 27

hydrodynamic instability

the horizontal shear of the mean wind

Question 28

This means that for barotropic instability to occur that the second derivative of the mean zonal wind must be equal

Answer 28

ß somewhere in the flow

Question 29

We can interpret this to mean that the absolute vorticity must have a

Answer 29

minimum or maximum value somewhere in the flow in order for barotropic instability to occur.

Question 30

……………………………………………………………….. minimum or maximum value somewhere in the flow in order for barotropic instability to occur.

Answer 30

We can interpret this to mean that the absolute vorticity must have a

Question 31

Barotropic instability is dependent upon

Answer 31

horizontal shear of the mean flow

Question 32

……………………………………….. is dependent upon horizontal shear of the mean flow

Answer 32

Barotropic instability

Question 33

to examine if barotropic instability is possible, the …………………………………………… must be examined

Answer 33

horizontal profile of the absolute vorticity

Question 34

The figure below shows the

Answer 34

zonal velocity, absolute vorticity and the second derivative of the velocity for an idealized westerly jet stream on the beta plane.

Question 35

The dashed line on the third diagram is

Answer 35

the value of beta

Question 36

There are ………………………………………………………. on both flanks of the jet, near the locations of ………………………………………………………………….

Answer 36

absolute vorticity minima and maxima

the inflection points in the velocity profile

Question 37

There are absolute vorticity minima and maxima on both flanks of the jet, near the locations of the inflection points in the velocity profile.

 Thus, the condition for ……………………………… is ……………………………………..

Answer 37

barotropic instability is met in these two regions

Question 38

There are absolute vorticity minima and maxima on both flanks of the jet, near the locations of the inflection points in the velocity profile.

 Thus, the condition for barotropic instability is met in these two regions.

 However, the presence of an inflection point

Answer 38

does not automatically mean that there is a minimum or maximum in the absolute vorticity.

Question 39

If beta is large compared to the second derivative of the velocity, such as for a

Answer 39

broad, weak jet at low latitudes

Question 40

if ………………………………………………………. such as for a broad, weak jet at low latitudes

Answer 40

beta is large compared to the second derivative of the velocity,

Question 41

If beta is large compared to the second derivative of the velocity, such as for a broad, weak jet at low latitudes, as shown in figure, then there will

Answer 41

not be any maxima in vorticity, even though there are inflection points in velocity profile.

Question 42

If beta is large compared to the second derivative of the velocity, such as for a broad, weak jet at low latitudes, as shown in figure, then there will not be any maxima in vorticity, even though there are inflection points in velocity profile.

 Thus, ……………. acts as

Answer 42

beta

stabilizing influencing against barotropic instability.

Question 43

Barotropic disturbances derive their energy from

Answer 43

the mean flow

Question 44

Barotropic disturbances derive their energy from the mean flow. Energy considerations show that

Answer 44

for a barotropic disturbance to grow it must tilt opposite to du/dy

Question 45

Since midlatitude disturbances tend to ……………………………………… they actually

Answer 45

tilt in the same direction as du/dy they actually lose energy back to the mean flow due to barotropic instability.

Question 46

Since midlatitude disturbances tend to tilt in the same direction as 􏲚􏲛􏲜⁄􏲚􏱥 they actually lose energy back to the mean flow due to barotropic instability.

 Thus, barotropic instability is not a viable way for

Answer 46

midlatitude disturbances to form and grow.

Question 47

Thus, barotropic instability is not a viable way for midlatitude disturbances to form and grow. However,

Answer 47

since midlatitude disturbance decay due to barotropic instability, they give up energy to the mean flow and help maintain the mean flow against friction.

Question 48

hus, barotropic instability is not a viable way for midlatitude disturbances to form and grow. However, since midlatitude disturbance decay due to barotropic instability, they give up energy to the mean flow and help maintain the mean flow against friction.

 Thus, barotropic instability is somewhat

Answer 48

important for the maintenance of the mean flow in the midlatitudes.

Question 49

Since barotropic instability is not a

Answer 49

feasible option for the formation of midlatitude cyclones, then another mechanism that must be invoked, is the Baroclinic Instability.

Question 50

For baroclinic instability it is the …………………………. rather than ………………………….. that is important

Answer 50

vertical shear

horizontal shear

Question 51

For baroclinic instability it is the vertical shear, rather than the horizontal shear, that is important.

 In an atmosphere with baroclinic instability, small random

Answer 51

perturbations in the turbulent flow of the atmosphere give rise to vertical displacements (warm air raising and cold air sinking).

Question 52

In an atmosphere with baroclinic instability, small random perturbations in the turbulent flow of the atmosphere give rise to vertical displacements (warm air raising and cold air sinking).

 Under suitable vertical wind shear, these ………………………………………… due to ………………………………………………..

Answer 52

vertical displacements will grow spontaneously due to conversion of potential energy to kinetic energy

Question 53

Under suitable vertical wind shear, these vertical displacements will grow spontaneously due to conversion of potential energy to kinetic energy. The baroclinic instability is also ………………….. dependent

Answer 53

wavelength

Question 54

Baroclinic instability is often studied for the simple case of

Answer 54

a two-layer fluid, for which waves are unstable if the following condition is true

Question 55

Baroclinic instability is often studied for the simple case of a two-layer fluid, for which waves are unstable if the following condition is true:

In the above expression (Eq.3):

U_T is the

Answer 55

vertical wind shear parameter (equal to half the difference in U between the two layers and

Question 56

Baroclinic instability is often studied for the simple case of a two-layer fluid, for which waves are unstable if the following condition is true:

In the above expression (Eq.3):

Answer 56

inversely proportional to static stability (large stability means small 􏲝).

Question 57

􏲞􏱄 is the vertical wind shear parameter (equal to half the difference in U between the two layers and

􏲝 is inversely proportional to static stability (large stability means small 􏲝).

 The above expression points out the

Answer 57

importance of vertical wind shear on baroclinic instability.

Question 58

There is also a ………………………. dependence for baroclinic instability

Answer 58

wavelength

Question 59

Answer 59

vertical shear

Question 60

Answer 60

wavenumber

Question 61

The influence of vertical shear and wavelength on the baroclinic instability can be understood by

Answer 61

plotting a curve between the two

Question 62

the influence of ………………………………………. on the baroclinic instability can be understood by plotting a curve between the two

Answer 62

vertical shear and wavelength

Question 63

The above curve demonstrates that

Answer 63

Question 64

The above curve demonstrates that for small values of shear the flow is stable, but as shear increases, instability will set in when 􏲞􏲟 is greater than unity.

 The plot also shows that there will be

Answer 64

Question 65

Analysis of baroclinic instability in the real (………………………………) atmosphere is much ………………………………………………

Answer 65

continuously stratified

more complicated than for the two-layer fluid.

Question 66

Analysis of baroclinic instability in the real (continuously stratified) atmosphere is much more complicated than for the two-layer fluid.

 Qualitatively the results are

Answer 66

similar, with instability depending on the vertical shear.

Question 67

Analysis of baroclinic instability in the real (continuously stratified) atmosphere is much more complicated than for the two-layer fluid.

 Qualitatively the results are similar, with instability depending on the vertical shear. However, in the real atmosphere there is always ………………………, so ………………………………

Answer 67

an unstable wave number, so barotropic instability is pervasive in the middle latitudes.

Question 68

The amount of instability, and growth rates, increase with

Answer 68

the amount of wind shear and other factors.

Question 69

……………………………………………………… increase with the amount of wind shear and other factors.

Answer 69

The amount of instability, and growth rates

Question 70

Baroclinic instability in the regions of ………………………………………………… is the mechanism by which ……………………………….

Answer 70

strong horizontal thermal gradients

midlatitude cyclones form

Question 71

Baroclinic instability in the regions of strong horizontal thermal gradients is the mechanism by which midlatitude cyclones form.

 Baroclinic instability (combined with ……………………………………) is also important for the …………………………………….

Answer 71

barotropic instability

formation of African Easterly waves.