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The AtmosphereThe Atmosphere
Structure and TemperatureStructure and Temperature
Atmosphere CharacteristicsAtmosphere Characteristics
Weather: the state of the atmosphere at a given time and place; “snapshot” in time
Climate: based on weather observations over many years (typically 30 years)
Weather properties: air temperature; humidity; type and amount of precipitation; air pressure; wind speed and direction
Weather: the state of the atmosphere at a given time and place; “snapshot” in time
Climate: based on weather observations over many years (typically 30 years)
Weather properties: air temperature; humidity; type and amount of precipitation; air pressure; wind speed and direction
Atmospheric CompositionAtmospheric Composition Mixture “Others”: Argon, CO2, water
vapor, traces of other gases Water vapor: source of
clouds and precipitation; absorbs heat from Earth and solar radiation
Condensation nuclei (particulates) : dust, pollen salt, soot, smoke (necessary for cloud formation as provides water with something to condense onto)
Mixture “Others”: Argon, CO2, water
vapor, traces of other gases Water vapor: source of
clouds and precipitation; absorbs heat from Earth and solar radiation
Condensation nuclei (particulates) : dust, pollen salt, soot, smoke (necessary for cloud formation as provides water with something to condense onto)
Height and StructureHeight and Structure Atmosphere thins with
increased altitude (gravity concentrates air at surface)
Temperature decreases with altitude in Troposphere (where weather occurs) and Mesosphere
Temperature increases with altitude in Stratosphere (ozone) and Thermosphere (O and N absorb short-wave, high energy solar radiation)
Atmosphere thins with increased altitude (gravity concentrates air at surface)
Temperature decreases with altitude in Troposphere (where weather occurs) and Mesosphere
Temperature increases with altitude in Stratosphere (ozone) and Thermosphere (O and N absorb short-wave, high energy solar radiation)
The AtmosphereThe Atmosphere
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Altitude and PressureAltitude and Pressure Air pressure is simply the
weight of the air above you The higher the altitude, the
fewer the air particles Fewer particles exert less
pressure, thus pressure decreases with an increase in altitude
Air that rises from the surface moves into layers with less pressure. This makes the air parcel expand and cool, forming clouds (adiabatic cooling).
Air pressure is simply the weight of the air above you
The higher the altitude, the fewer the air particles
Fewer particles exert less pressure, thus pressure decreases with an increase in altitude
Air that rises from the surface moves into layers with less pressure. This makes the air parcel expand and cool, forming clouds (adiabatic cooling).
AdiabaticAdiabatic
Describes a change in temperature resulting from the expansion or compression of air
Air that rises will expand (due to less pressure from surrounding particles) and will cool adiabatically
Air that descends will compress (due to more pressure from surrounding particles) and will warm adiabatically
Describes a change in temperature resulting from the expansion or compression of air
Air that rises will expand (due to less pressure from surrounding particles) and will cool adiabatically
Air that descends will compress (due to more pressure from surrounding particles) and will warm adiabatically
Earth-Sun RelationshipsEarth-Sun Relationships
Solar energy is not distributed evenly over Earth’s surface
Varies with latitude, time of day, and season of the year
Unequal heating creates winds and drives ocean currents
Winds and ocean currents transport heat from warmer to colder regions in an attempt to balance energy differences
Solar energy is not distributed evenly over Earth’s surface
Varies with latitude, time of day, and season of the year
Unequal heating creates winds and drives ocean currents
Winds and ocean currents transport heat from warmer to colder regions in an attempt to balance energy differences
Earth’s OrientationEarth’s Orientation
Seasonal changes occur because Earth’s position relative to the sun continually changes as it travels its orbit.
Due to the Earth’s tilt (23.5º) and revolution around the sun, energy received at given latitudes changes with time. This creates our seasons as well as seasonal variations in severe weather.
Seasons ARE NOT due to changes in distance from the sun. (We have summer when farthest from the sun, and winter when closest.)
Seasonal changes occur because Earth’s position relative to the sun continually changes as it travels its orbit.
Due to the Earth’s tilt (23.5º) and revolution around the sun, energy received at given latitudes changes with time. This creates our seasons as well as seasonal variations in severe weather.
Seasons ARE NOT due to changes in distance from the sun. (We have summer when farthest from the sun, and winter when closest.)
Heating the AtmosphereHeating the Atmosphere
Heat is the energy transferred from one object to another because of a difference in their temperatures.
When energy is transferred to the gas atoms and molecules in the air, particles move faster and air temperature increases.
When air transfers energy to a cooler object, its particles move slower and air temperature decreases.
Three mechanisms of heat transfer: conduction, convection and radiation
Heat is the energy transferred from one object to another because of a difference in their temperatures.
When energy is transferred to the gas atoms and molecules in the air, particles move faster and air temperature increases.
When air transfers energy to a cooler object, its particles move slower and air temperature decreases.
Three mechanisms of heat transfer: conduction, convection and radiation
ConductionConduction
Transfer of heat through matter by molecular activity
Energy of molecules transferred by collisions from one to another
Heat flows from higher to lower temperatures
Air is a poor heat conductor, so conduction only occurs between land and air in direct contact with it
Transfer of heat through matter by molecular activity
Energy of molecules transferred by collisions from one to another
Heat flows from higher to lower temperatures
Air is a poor heat conductor, so conduction only occurs between land and air in direct contact with it
ConvectionConvection
Transfer of heat by mass movement or circulation within a substance
Takes place in fluids (ocean and air) and solids (mantle)
Air warmed at surface rises (less dense), cools adiabatically and sinks (more dense)
Most heat transfer within the atmosphere is due to convection.
Transfer of heat by mass movement or circulation within a substance
Takes place in fluids (ocean and air) and solids (mantle)
Air warmed at surface rises (less dense), cools adiabatically and sinks (more dense)
Most heat transfer within the atmosphere is due to convection.
RadiationRadiation
All objects (hot or cold) emit radiant energy, although hotter objects emit more total energy
Hottest radiating bodies produce the shortest wavelengths of maximum radiation
Solar energy reaches earth by radiation Some energy (depending on wavelength) is
scattered, some reflected and some absorbed at the Earth’s surface.
All objects (hot or cold) emit radiant energy, although hotter objects emit more total energy
Hottest radiating bodies produce the shortest wavelengths of maximum radiation
Solar energy reaches earth by radiation Some energy (depending on wavelength) is
scattered, some reflected and some absorbed at the Earth’s surface.
Temperature and WindTemperature and Wind
Temperature differences (due to unequal heating of the Earth’s surface) create pressure differences. (Colder air is “heavier” so it exerts greater pressure.)
Wind is the result of pressure differences. Wind flows from areas of HIGH pressure to areas of LOW pressure in an attempt to make the atmosphere more uniform.
Temperature differences (due to unequal heating of the Earth’s surface) create pressure differences. (Colder air is “heavier” so it exerts greater pressure.)
Wind is the result of pressure differences. Wind flows from areas of HIGH pressure to areas of LOW pressure in an attempt to make the atmosphere more uniform.
Factors Affecting WindFactors Affecting Wind
If Earth did not rotate and friction between air and Earth didn’t exist, air would flow in a straight line from high to low pressure. However…
Three factors combine to control wind: pressure differences, the Coriolis effect, and friction.
If Earth did not rotate and friction between air and Earth didn’t exist, air would flow in a straight line from high to low pressure. However…
Three factors combine to control wind: pressure differences, the Coriolis effect, and friction.
Pressure DifferencesPressure Differences
The greater the difference in pressure, the greater the wind speed.
Isobars connect places of equal air pressure. The closer the isobars, the faster the wind speed.
Pressure Gradient: amount of pressure change occurring over a given distance
The greater the difference in pressure, the greater the wind speed.
Isobars connect places of equal air pressure. The closer the isobars, the faster the wind speed.
Pressure Gradient: amount of pressure change occurring over a given distance
Coriolis EffectCoriolis Effect
Describes how Earth’s rotation affects moving objects.
All free-moving objects or fluids (including the wind) are deflected to the RIGHT of their path in the N.H. and to the LEFT of their path in the S. H.
Wind actually moves in a straight line, but the Earth rotates beneath it, giving the “illusion” of bending.
Describes how Earth’s rotation affects moving objects.
All free-moving objects or fluids (including the wind) are deflected to the RIGHT of their path in the N.H. and to the LEFT of their path in the S. H.
Wind actually moves in a straight line, but the Earth rotates beneath it, giving the “illusion” of bending.
Earth’s Rotation and Weather Systems
Earth’s Rotation and Weather Systems
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FrictionFriction
Important only within a few kilometers of Earth’s surface.
Acts to slow air movement, which changes wind direction.
When air is above friction layer, the pressure gradient causes air to move across the isobars. At that time, the Coriolis effect acts at right angles to this motion. The faster the wind, the greater the deflection.
Important only within a few kilometers of Earth’s surface.
Acts to slow air movement, which changes wind direction.
When air is above friction layer, the pressure gradient causes air to move across the isobars. At that time, the Coriolis effect acts at right angles to this motion. The faster the wind, the greater the deflection.
Pressure Centers and WindsPressure Centers and Winds
Cyclones (low pressure centers)
Pressure decreases from outer isobars to center
Winds flow counterclockwise into system
Associated with overcast skies and rain
Cyclones (low pressure centers)
Pressure decreases from outer isobars to center
Winds flow counterclockwise into system
Associated with overcast skies and rain
Anticyclones (high pressure centers)
Pressure increases from outer isobars to center
Winds flow clockwise out of system
Associated with fair weather and blue skies
Anticyclones (high pressure centers)
Pressure increases from outer isobars to center
Winds flow clockwise out of system
Associated with fair weather and blue skies
Weather and Air PressureWeather and Air Pressure
Low pressure at surface causes air to convergence and rise. Rising air cools adiabatically and forms clouds.
High pressure at surface causes air to diverge (air subsides from aloft and warms adiabatically) creating clear, blue skies.
Low pressure at surface causes air to convergence and rise. Rising air cools adiabatically and forms clouds.
High pressure at surface causes air to diverge (air subsides from aloft and warms adiabatically) creating clear, blue skies.
Global WindsGlobal Winds
Recall that a non-rotating Earth would create two main convection cells with air flowing from the poles to the equator (high to low)
The Earth’s rotation breaks this convection into smaller cells
The behavior of winds within these cells produce global wind belts.
Recall that a non-rotating Earth would create two main convection cells with air flowing from the poles to the equator (high to low)
The Earth’s rotation breaks this convection into smaller cells
The behavior of winds within these cells produce global wind belts.
El Nino El Nino
Under normal conditions, trade winds and a strong equatorial ocean current flows toward the west.
Flow encourages upwelling of cold nutrient-filled water from below as water above “pushed away” from the wind.
Food source for fish
Under normal conditions, trade winds and a strong equatorial ocean current flows toward the west.
Flow encourages upwelling of cold nutrient-filled water from below as water above “pushed away” from the wind.
Food source for fish
More on El Nino…More on El Nino…
At irregular intervals of three to seven years, these warm countercurrents become unusually strong and replace normally cold offshore water with warm equatorial waters (El Nino)
Produces abnormal weather patterns for Ecuador and Peru (excessive rainfall).
Fishing industry impacted.
At irregular intervals of three to seven years, these warm countercurrents become unusually strong and replace normally cold offshore water with warm equatorial waters (El Nino)
Produces abnormal weather patterns for Ecuador and Peru (excessive rainfall).
Fishing industry impacted.
La NinaLa Nina
Opposite of El Nino Occurs when surface temperatures in the eastern
Pacific are colder than average Distinctive set of weather patterns Colder than normal air over Pacific Northwest and
northern Great Plains, but warmer over much of the rest of the United States
Greater precipitation over Northwest than usual Can increase hurricane activity; hurricane
damages 20X greater in U.S. during La Nina years
Opposite of El Nino Occurs when surface temperatures in the eastern
Pacific are colder than average Distinctive set of weather patterns Colder than normal air over Pacific Northwest and
northern Great Plains, but warmer over much of the rest of the United States
Greater precipitation over Northwest than usual Can increase hurricane activity; hurricane
damages 20X greater in U.S. during La Nina years
