ST L2: Thunderstorm Cells and Supercells / Latent Heat and the Sun, the Source of Atmospheric Heat

Question 1

Life cycle of one thunderstorm cell?

Answer 1

5-15 mins

Question 2

Briefly state stages of thunderstorms.

Answer 2

1: cumulus phase
2: mature stage
3: dissipating stage
4. storm propagation

Question 3

Describe the cumulus phase.

Answer 3

Thunderstorms starts as a cumulus phase, having all updraft, no precipitation (i.e., rain, snow, sleet, hail, etc), and no anvil

Question 4

Describe the mature stage.

Answer 4

having both up and downdrafts (both of which could be violent), having precipitation (which could be heavy) and the start of an anvil with a sharp or crisp outline

Question 5

Describe the dissipating stage of thunderstorms.

Answer 5

with only downdrafts, weaker precipitation, and a large anvil with a diffuse outline
However, even after the original (mother) storm has dissipated, the gust front that it earlier created might encounter some more warm boundary layer air before it dies.

Question 6

Describe the process of storm propagation.

Answer 6

When the gust front encounters some more warm boundary layer air before dying, the cold gust-front air plows under the warmer, humid boundary layer air, triggering an updraft that can spawn a new (daughter) thunderstorm.

Question 7

Describe some organization of thunderstorms.

Answer 7

orographic thunderstorms, multicell storms, squall-line thunderstorms, air mass thunderstorms, supercell storms

Question 8

Describe orographic thunderstorms.

Answer 8

Mountain-related storms. They sometimes stay over mountains because of the wind shear that fuels the storm from the boundary layer. These unmoving storms can cause flash floods

Question 9

Describe multi-cell storms

Answer 9

Thunderstorm with many cells. Most common type of thunderstorm. In some multi-cell storms, there is a flanking line of clouds sticking out from main updraft. In the flanking line, there are often new cells in the cumulus stage. As they grow, the winds blow cells into main updraft. By then, cells are often in the mature stage.

Question 10

Describe squall-line thunderstorms.

Answer 10

Thunderstorms that form in lines called squall lines, where heaviest rain cells merge into a long narrow line. (special type of multi-cell storm). These lines of storms can move toward the east or southeast, even though individual thunderstorms within them are moving northeast. These storms can be triggered along strong cold front or strong air-mass boundaries.

Question 11

Describe air mass thunderstorms.

Answer 11

garden-variety storms that pop up in scattered locations within a large air mass due to strong heating of the ground by the Sun. These don’t need to form along fronts or boundaries. They are often short lived.

Question 12

Describe supercell storms

Answer 12

Often severe, long lasting, often rotating, having violent wind gusts, and can cause tornadoes and hail. Supercell thunderstorms are often the most dangerous variety, and often consist of just ONE rotating cell.
Types of the cell:
- low precipitation (LP) supercell: produce lots of hail;
- classic supercell: have rainy downdrafts and rain-free updrafts; and
- high precipitation (HP) supercell: have updrafts that are mostly surrounded by rain.

Supercells can last for 30 minutes and longer, due to favorable wind shear in the environment. There is often low altitude flow from the southeast, mid-altitude flow from the southwest, and fast upper-level flow is from the west. It is this mid-level wind (at roughly 5 km above ground) that steers thunderstorms toward the northeast, allowing the supercell storm to continuously draw in new humid boundary-layer air as fuel.

Question 13

What is wind shear?

Answer 13

when the wind speed or direction changes with altitude

Question 14

What is a mesocyclone?

Answer 14

When the whole supercell thunderstorm is rotating. Barrel-shaped look of the storm. Sometimes there are cloud striation that spiral around main updraft clouds. Mesocyclone rotation can be observed by Doppler radar.

Question 15

What is the Doppler Radar?

Answer 15

Detects motions inside the storm.

Question 16

From what are the strongest tornadoes formed?

Answer 16

Mesocyclone rotations

Question 17

Where do thunderstorm cells and supercells get their fuel/energy from?

Answer 17

Warm humid air near the ground.

Question 18

What is a remote sensor?

Answer 18

an instrument that is remote from (outside of) the storm, but can measure the storm.

Question 19

What is dBZ?

Answer 19

Disaster intensity scale for rainfall. Quantifies rain rate over specific area. Measure of the reflectivity of a radar signal reflected off water vapour.

Question 20

Sensible heat is consumed to _____ water. It is absorbed from the air surrounding the water and is “hidden” (stored) in the _______.
Once hidden, it is called _____.
As air gives its heat up, it becomes _____. It also becomes more _____ due to increased amount of water vapour.

Answer 20

evaporate (change its phase from liquid to vapour)

water vapour.

latent heat.

cooler.

humid.

Question 21

What is the main component of thunderstorms?

Answer 21

Rain. By spotting, observing, monitoring rainfall is a way of monitoring larger systems like multicell thunderstorms.

Question 22

What is one major way storms get their energy?

Answer 22

Through water vapour that is drawn into the storm and then condensed to release latent heat.

Question 23

For amount of energy consumed or released, if the phase change releases latent heat into sensible heat to warm the air, then L value is ____. If phase change absorbs latent heat from sensible heat and cools the air, then the L value is ____.

Answer 23

+ve; -ve

Question 24

The net result is that evaporation ____ the air, and condensation _____ the air. To find how much the air temperature changes due to water phase changes, we can combine the concepts of mixing ratio, sensible heat, and latent heat.

Answer 24

cools ; warms

Question 25

What is the top of the atmosphere called?

Answer 25

thermosphere

Question 26

What is the middle of the atmosphere called? Where is most of the ultraviolet light absorbed?

Answer 26

stratosphere is middle of atmosphere. stratopause is highest part of stratosphere. It becomes hot from absorbing the UV solar energy.

Question 27

What is the bottom of the atmosphere called? Describe it.

Answer 27

The troposphere. Bottom 11 km. Visible light can shine through the non-cloudy, non-polluted parts of the troposphere. Solar energy that reached this area is absorbed by Earth’s surface. Warm surface heats air in the troposphere.

Question 28

Where do most storms happen?

Answer 28

Troposphere.

Question 29

How is the bottom of the atmosphere heated?

Answer 29

Heated by the warm ground or ocean, not directly by the Sun.

Question 30

When sunlight reaches the surface, some _____ back into space (see figure below). Also, a portion is intercepted by clouds before it reaches the surface, and _____ back to space (which is why clouds look bright white in visible satellite images during daytime. However, there is a remainder that is _____ by the ground, causing the Earth’s surface to get warm.

Answer 30

reflects ; scattered; absorbed

Question 31

What kind of heat causes humidity to rise?

Answer 31

latent heat; when liquid water evaporates

Question 32

What causes air to et warmer?

Answer 32

sensible heat

Question 33

What kind of heat does sun give off?

Answer 33

radiative heat

Question 34

Which two heat sources are the fuel for storms? How to quantify/measure?

Answer 34

Sensible and latent heat. Measured by air temp. and humidity.

Question 35

Through what method is heat lost?

Answer 35

Infrared radiation (IR)

Question 36

What time is the greatest accumulation of heat?

Answer 36

Near sunset.

Question 37

What times are most likely for thunderstorm formation?

Answer 37

Late afternoon, early evening. Most humid, end of each charging cycle.

Question 38

In which regions are thunderstorms most likely to form?

Answer 38

Closer to the equator, near warm ocean currents. (greatest supply of heat and moisture.) E.g. Alberta, Ontario, Manitoba, Quebec, Florida USA, states near the Gulf of Mexico (at least 90 days of storms in USA).

Question 39

What is advection?

Answer 39

Movement of heat and humidity by the wind.

Question 40

What two mechanisms draw the Sun’s energy into storms?

Answer 40

Advection of heat (temperature), advection of moisture (humidity)

Question 41

What is the positive feedback process?

Answer 41

Extra warming (due to advection mechanisms) strengthens storm and attracts even more humid air. Storm consumes and condenses so much water vapour that the rest falls out as precipitation.

Question 42

How is reflectivity important for storms?

Answer 42

It is an indication of storm strength. Storms containing more liquid water and precipitation reflect more microwave energy from the radar.

Question 43

What colour do most intense storms appear in echoes on the radar?

Answer 43

yellow and red.

Question 44

How to measure rainfall rate from vigorous storms?

Answer 44

the rate of increase of depth of water in a rain gauge.

Question 45

What is the rainfall rate (RR) a direct indication of?

Answer 45

the average warming rate in the storm (due to latent heating)
(Change in temp/Change in time = a * RR) where a = 0.388K/mm rain)

Question 46

What kinds of clouds are smaller and non-precipitating?

Answer 46

clouds that do no have the special organization. they do not take max. advantage of the positive feedback associated with latent heat release.

Question 47

Which clouds have the proper organization to become violent thunderstorms?

Answer 47

cumulonimbus clouds

Question 48

The Sun heats the Earth’s surface, which warms the air and ____ water. This warm humid air is the fuel for storms, and can be advected into the storm by ____. Once this fuel is in the storm, water vapour ____ and releases ____heat, which both provides ____ for the storm and creates ____. Organized storms (with ____ feedback) are stronger.

Answer 48

evaporates; winds; condenses; latent; energy; precipitation; positive