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Learn about the chemistry of tropospheric pollutants, dry and wet deposition processes, boundary layer dynamics, and global circulation patterns influencing air pollution. Explore how pollutants are removed from the atmosphere and the impact of global circulation on air quality.
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METO 637 Lesson 13
The Troposphere • In the Stratosphere we had high energy photons so that oxygen atoms and ozone dominated the chemistry. • In the troposphere we have lower energy photons, and the chemistry is dominated by the OH and NO3 radicals. • OH is generated photochemically (i.e. only during the day), NO3 is rapidly photolyzed during the day, so it can only survive at night. O(1D) + H2O → OH + OH : NO2 + O3 → NO3 + O2 • NO3 is generally less reactive then OH, its peak concentration is higher. • OH provides an efficient scavenging mechanism for both natural and anthropogenic trace constituents
Dry and Wet Deposition • Dry deposition – removal of gases and particles by a direct transfer from the atmosphere to the surface. • Wet deposition – removal of gases and particles carried to the surface in water – rain, snow, fog etc. • Dry deposition is known for SO2, O3, CO2, and SO3. • Wet deposition of gaseous species requires that they be water soluble. Terms used are rainout, or washout. • Acid rain is an example of the rainout of sulfurous and nitric acids, produced in polluted atmospheres.
Dry Deposition • Three separate steps (1) Species must be transported close to the surface (2) Species must cross to the surface (3) Species must be taken up on the surface. • Dampness of the surface can be critical for some species, e.g. SO2, O3, HNO3
Wet deposition • Wet deposition – incorporation into falling precipitation (washout), or into cloud droplets (rainout). • Chemical conversions can occur within the droplets.
Boundary Layer • Lower limit of the troposphere is seen as a layer and not the surface – known as the boundary layer • As the winds flow across the surface they undergo friction – which generates turbulent eddies in the atmosphere. • This region of high turbulent mixing is generally confined to altitudes up to 0.5 – 2km in the day, and lower at night • The region above the boundary layer is known as the free troposphere • In the free troposphere the kinetic energy is associated with large scale disturbances – periods of a day or more. • In the boundary layer the periods are of the order of minutes
GLOBAL CIRCULATION • George Hadley first suggested in 1735 the general concept of atmospheric circulation. • He used a single cell, to explain the existence of the easterly winds at the surface • Cold air at the pole - high pressure at the surface. Warm air at the equator - low pressure at the surface. Pressure gradient force at surface will move air from pole to equator at surface. Return path at high altitudes. • The action of the Coriolis force on this southerly flow at the surface will produce easterly winds. • But we find westerly winds at mid-latitudes – why?
GLOBAL CIRCULATION • In reality the atmosphere cannot maintain a single cell, instead there are three cells, with boundaries at about 30 and 60 degrees latitude. • This results in sinking air at 30 N and 30 S. But sinking air suppresses cloud development and precipitation. Hence most of the worlds deserts occur along these latitudes. • At mid-latitudes the prevailing wind in the free troposphere is westerly (mid-latitude westerlies) • Between the equator and 30 degrees we get easterlies – trade winds. • The free troposphere also has lower temperatures than at the surface – reaction rates are slower, and pollutants can travel large distances before they are removed chemically.