Atmospheric Moisture

Atmospheric Moisture

• State Changes of Water• Humidity• Adiabatic Cooling• What Makes Air Rise?• Atmospheric Stability

Terms• Adiabatic

– Without the transfer of heat

• Exothermic– Heat-releasing

• Endothermic– Heat-absorbing

Terms• Humidity

– How much water vapor the air is holding

• Parcel– A volume of air assumed to have the same

properties throughout (temp, humidity, etc.)– Assumed to behave independently of

surrounding (ambient) air

• Environmental lapse rate (ELR)

Terms

• Environmental lapse rate (ELR)

– Rate at which temperature drops with increasing altitude in the troposphere

– Variable, but average = 6.5°C/km

State Changes of Water

PSCI 131: Atmospheric Moisture

Water’s State Changes

PSCI 131: Atmospheric Moisture

• Transfer of heat between water molecules & their surroundings

• Either endothermic or exothermic

• Heat source: reradiation of solar energy from ground

PSCI 131: Atmospheric Moisture: Water’s State Changes

Blue arrows: exothermic Red arrows: endothermic

Water’s State Changes

PSCI 131: Atmospheric Moisture

• Why does sweating cool you off?

• Sweat evaporates (endothermic), absorbing heat from your skin

Humidity

PSCI 131: Atmospheric Moisture

HumidityPSCI 131: Atmospheric Moisture

• Evaporation from Earth’s surface (especially oceans) adds water vapor to the air

• A given mass of air at a given temperature can only hold so much water in vapor form

• If this limit is exceeded, excess vapor condenses to liquid

Ways of Expressing Air’s Humidity

PSCI 131: Atmospheric Moisture: Humidity

• Relative humidity

• Dewpoint temperature

Relative HumidityPSCI 131: Atmospheric Moisture: Humidity

• Saturation content

– Maximum amount of vapor an air parcel can hold

– Controlled by air’s temperature

Relative HumidityPSCI 131: Atmospheric Moisture: Humidity

• Vapor content– How much vapor the parcel is actually

holding

• RH = vapor content / saturation content

Relative HumidityPSCI 131: Atmospheric Moisture: Humidity

• Relative humidity will change if either of the following happens:

– Temperature changes (more common cause)

– Vapor content changes

Relative HumidityPSCI 131: Atmospheric Moisture: Humidity

• Example – Parcel’s vapor content is 10g (given)– Parcel temp: 25 degrees C– Therefore, saturation content is 20g (from table)

• RH = 10g/ 20g = 50%

Relative Humidity

PSCI 131: Atmospheric Moisture: Humidity

• Example (cont.)– Parcel’s vapor content changes to 14g– Parcel temp remains 25 degrees C– Therefore, saturation content is still 20g

• RH = 14g/ 20g = 70%

• RH has risen because vapor content has risen

Relative HumidityPSCI 131: Atmospheric Moisture: Humidity

• Example (cont.)– Vapor content is still 14g– Parcel cools to 20 degrees C– New saturation content is 14g

• RH = 14g/ 14g = 100%

• RH has risen because temp has fallen

• Air is saturated

Relative Humidity: Summary

PSCI 131: Atmospheric Moisture: Humidity

• Higher vapor content = higher RH

• Lower temp = lower sat. content = higher RH

Relative Humidity: Summary

PSCI 131: Atmospheric Moisture: Humidity

• RH highest when temp is lowest

• & vice versa

Dewpoint Temperature

PSCI 131: Atmospheric Moisture: Humidity

• Temp at which air parcel is saturated (100% RH)

• More vapor in parcel (more humid) = higher dewpoint

Adiabatic Cooling

PSCI 131: Atmospheric Moisture

Adiabatic CoolingPSCI 131: Atmospheric Moisture: Adiabatic Cooling

Air parcel rises, pressure drops, air cools (no heat energy transferred).

Adiabatic Cooling Rates

• Dry adiabatic lapse rate (DAR): 10° C /km– If RH less than 100%

• Wet adiabatic lapse rate (WAR): 5-9° C /km– If RH equals100%– Depends on vapor content– Always less than DAR

PSCI 131: Atmospheric Moisture : Adiabatic Cooling

Condensation Level

• Altitude at which rising, cooling air’s temp reaches dew point and condensation begins

PSCI 131: Atmospheric Moisture: Adiabatic Cooling

Condensation LevelPSCI 131: Atmospheric Moisture: Adiabatic Cooling

• Several things are true when air has risen to its condensation level:– Air has cooled to its dewpoint– RH = 100%– Condensation can occur (usually as clouds)

PSCI 131: Atmospheric Moisture: Adiabatic Cooling

Condensation Level

• Adiabatic lapse rates (WAR and DAR): rates at which air parcel cools as it rises

• Env lapse rate (ELR): rate at which temperature around parcel decreases with altitude

PSCI 131: Atmospheric Moisture: Adiabatic Cooling

Adiabatic Lapse Rates vs Env Lapse Rate

What Makes Air Rise?

PSCI 131: Atmospheric Moisture

Four Processes

• Orographic Lifting

PSCI 131: Atmospheric Moisture: What Makes Air Rise?

Four Processes

Frontal wedging

PSCI 131: Atmospheric Moisture: What Makes Air Rise?

Four ProcessesConvergence

PSCI 131: Atmospheric Moisture: What Makes Air Rise?

Four Processes

Convective Lifting

PSCI 131: Atmospheric Moisture: What Makes Air Rise?

Atmospheric Stability

PSCI 131: Atmospheric Moisture

What Is It?

• Balance between DAR, WAR, and ELR

• How likely a given air parcel is to rise, and how far up it will go

• The “weather maker”

PSCI 131: Atmospheric Moisture: Atmospheric Stability

Three Combinations

• Absolute stability

• Absolute instability

• Conditional instability

PSCI 131: Atmospheric Moisture: Atmospheric Stability

• Adiabatic lapse rates (WAR and DAR): rates at which air parcel cools as it rises

• Env lapse rate (ELR): rate at which temperature around parcel decreases with altitude

Adiabatic Lapse Rates vs Env Lapse Rate

PSCI 131: Atmospheric Moisture: Atmospheric Stability

Absolute Instability

• ELR > DAR > WAR

• Surrounding air cools faster than parcel, so parcel is always warmer

• Parcel “wants” to keep rising

• Think of a hot-air balloon

PSCI 131: Atmospheric Moisture: Atmospheric Stability

Absolute Instability

PSCI 131: Atmospheric Moisture: Atmospheric Stability

Absolute Instability• Weather effects

– Lots of condensation– Heavy clouds– Lots of precip– Storms

PSCI 131: Atmospheric Moisture: Atmospheric Stability

Absolute Stability

•DAR > WAR > ELR

•Rising parcel cools faster than surrounding air, so parcel is always colder

•“Wants” to descend

PSCI 131: Atmospheric Moisture: Atmospheric Stability

Absolute Stability

•Will only rise if forced to– Orographic lifting, frontal wedging, etc.

•A “cold-air balloon”

PSCI 131: Atmospheric Moisture: Atmospheric Stability

Absolute Stability

PSCI 131: Atmospheric Moisture: Atmospheric Stability

Absolute Stability

•Weather effects– Fair weather– Light to moderate clouds and precip

• If forced above condensation level

– No storms

PSCI 131: Atmospheric Moisture: Atmospheric Stability

Conditional Instability

• DAR > ELR > WAR

• Rising parcel cools faster than surrounding air while RH is less than 100% and air is cooling at DAR– Parcel always cooler while below

condensation level– Must be forced to rise

PSCI 131: Atmospheric Moisture: Atmospheric Stability

Conditional Instability

• Surrounding air cools faster than parcel once RH = 100% –Parcel always warmer above condensation level

• Think of a cold-air balloon that is forced to rise to condensation level, at which it changes into a hot-air balloon

PSCI 131: Atmospheric Moisture: Atmospheric Stability

Conditional InstabilityPSCI 131: Atmospheric Moisture: Atmospheric Stability

Conditional Instability

• Weather effects–Fair weather–Heavy clouds and precip/storms if forced above condensation level

PSCI 131: Atmospheric Moisture: Atmospheric Stability

End of Chapter