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Atmospheric Water

Atmospheric Water. Global energy balance Atmospheric circulation Atmospheric water vapor Reading: Sections 3.3 and 3.4 for next Tues. Atmospheric Water. Global energy balance Atmospheric circulation Atmospheric water vapor. Radiation. Basic laws Stefan-Boltzman Law

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Atmospheric Water

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  1. Atmospheric Water • Global energy balance • Atmospheric circulation • Atmospheric water vapor • Reading: Sections 3.3 and 3.4 for next Tues

  2. Atmospheric Water • Global energy balance • Atmospheric circulation • Atmospheric water vapor

  3. Radiation • Basic laws • Stefan-Boltzman Law • R = emitted radiation (W/m2) • T = absolute temperature (K), • and s = 5.67x10-8W/m2-K4 • with e = emissivity (0-1) • Water, Ice, Snow (0.95-0.99) • Sand (0.76) Valid for a Black body or “pure radiator” “Gray bodies emit a proportion of the radiation of a black body

  4. Net Radiation, Rn Ri Incoming Radiation • Ro =aRi Reflected radiation • = albedo (0 – 1) Re Rn Net Radiation Average value of Rn over the earth and over the year is 105 W/m2

  5. Net Radiation, Rn H – Sensible Heat LE – Evaporation G – Ground Heat Flux Rn Net Radiation Average value of Rn over the earth and over the year is 105 W/m2

  6. Energy Balance of Earth 70 20 100 6 6 26 4 38 15 19 21 Sensible heat flux 7 Latent heat flux 23 51 http://www.uwsp.edu/geo/faculty/ritter/geog101/textbook/energy/radiation_balance.html

  7. Diurnal Variation Diurnal variation of fluxes, July 2003 San Marcos Basin Downward shortwave Upward Longwave Downward longwave Upward shortwave Ground Fluxes in W/m2 Latent Sensible

  8. Energy Balance in the San Marcos Basin from the NARR (July 2003) Note the very large amount of longwave radiation exchanged between land and atmosphere Average fluxes over the day 495 61 72 112 3 310 415 Net Shortwave = 310 – 72 = 238; Net Longwave = 415 – 495 = - 80

  9. Increasing carbon dioxide in the atmosphere (from about 300 ppm in preindustrial times) We are burning fossil carbon (oil, coal) at 100,000 times the rate it was laid down in geologic time

  10. Absorption of energy by CO2

  11. Atmospheric Water • Global energy balance • Atmospheric circulation • Atmospheric water vapor

  12. Heating of earth surface is uneven Solar radiation strikes perpendicularly near the equator (270 W/m2) Solar radiation strikes at an oblique angle near the poles (90 W/m2) Emitted radiation is more uniform than incoming radiation Heating of earth surface Amount of energy transferred from equator to the poles is approximately 4 x 109 MW

  13. Hadley circulation Atmosphere (and oceans) serve to transmit heat energy from the equator to the poles Warm air rises, cool air descends creating two huge convective cells.

  14. Conservation of Angular Momentum (Coriolis Force) No external forces on air, so mV1r1 = mV2r2 mV1r1 r1 < r2 so V1 > V2 mV2r2 Intertropical Convergence Zone V1 r1 Earth rotation r2 V2 Earth rotation Looking down from North Pole, earth is rotating counterclockwise Near equator, air starts to “fall behind” the earth

  15. Atmospheric circulation Circulation cells Polar Cell • Hadley cell • Ferrel Cell • Polar cell Ferrel Cell Winds • Tropical Easterlies/Trades • Westerlies • Polar easterlies Latitudes • Intertropical convergence zone (ITCZ)/Doldrums • Horse latitudes • Subpolar low • Polar high

  16. Effect of land mass distribution Uneven distribution of land and ocean, coupled with different thermal properties creates spatial variation in atmospheric circulation A) Idealized winds generated by pressure gradient and Coriolis Force. B) Actual wind patterns owing to land mass distribution

  17. Shifting in Intertropical Convergence Zone (ITCZ) Owing to the tilt of the Earth's axis in orbit, the ITCZ shifts north and south.  Southward shift in January Creates wet Summers (Monsoons) and dry winters, especially in India and SE Asia Northward shift in July

  18. ITCZ movement http://iri.ldeo.columbia.edu/%7Ebgordon/ITCZ.html

  19. Atmospheric Water • Global energy balance • Atmospheric circulation • Atmospheric water vapor

  20. Structure of atmosphere

  21. Atmospheric water • Atmospheric water exists • Mostly as gas or water vapor • Liquid in rainfall and water droplets in clouds • Solid in snowfall and in hail storms • Accounts for less than 1/100,000 part of total water, but plays a major role in the hydrologic cycle

  22. Water vapor Suppose we have an elementary volume of atmosphere dV and we want quantify how much water vapor it contains Water vapor density dV ma = mass of moist air mv = mass of water vapor Air density Atmospheric gases: Nitrogen – 78.1% Oxygen – 20.9% Other gases ~ 1% http://www.bambooweb.com/articles/e/a/Earth's_atmosphere.html

  23. Specific Humidity, qv • Specific humidity measures the mass of water vapor per unit mass of moist air • It is dimensionless

  24. Vapor pressure, e • Vapor pressure, e, is the pressure that water vapor exerts on a surface • Air pressure, p, is the total pressure that air makes on a surface • Ideal gas law relates pressure to absolute temperature T, Rv is the gas constant for water vapor • 0.622 is ratio of mol. wt. of water vapor to avg mol. wt. of dry air (=18/28.9)

  25. Dalton’s Law of Partial Pressures John Dalton studied the effect of gases in a mixture. He observed that the Total Pressure of a gas mixture was the sum of the Partial Pressure of each gas. P total = P1 + P2 + P3 + .......Pn The Partial Pressure is defined as the pressure of a single gas in the mixture as if that gas alone occupied the container. In other words, Dalton maintained that since there was an enormous amount of space between the gas molecules within the mixture that the gas molecules did not have any influence on the motion of other gas molecules, therefore the pressure of a gas sample would be the same whether it was the only gas in the container or if it were among other gases. http://members.aol.com/profchm/dalton.html

  26. Avogadro’s law Equal volumes of gases at the same temperature and pressure contain the same number of molecules regardless of their chemical nature and physical properties. This number (Avogadro's number) is 6.023 X 1023 in 22.41 L for all gases. Dry air ( z = x+y molecules) Moist air (x dry and y water vapor) Dry air (21% O2, 78% N2, 1% other) Md ~ 0.22*32+0.78*28 ~ 28.9 Water vapor (H2O) Mv = 2*1 + 16 = 18 rd = (x+y) * Md/Volume rm = (x* Md + y*Mv)/Volume Moist air is lighter than dry air rm < rd, thus moist air is less dense than dry air

  27. Saturation vapor pressure, es Saturation vapor pressure occurs when air is holding all the water vapor that it can at a given air temperature Vapor pressure is measured in Pascals (Pa), where 1 Pa = 1 N/m2 1 kPa = 1000 Pa

  28. Relative humidity, Rh es e Relative humidity measures the percent of the saturation water content of the air that it currently holds (0 – 100%)

  29. Dewpoint Temperature, Td e Td T Dewpoint temperature is the air temperature at which the air would be saturated with its current vapor content

  30. Water vapor in an air column • We have three equations describing column: • Hydrostatic air pressure, dp/dz = -rag • Lapse rate of temperature, dT/dz = - a • Ideal gas law, p = raRaT • Combine them and integrate over column to get pressure variation elevation 2 Column Element, dz 1

  31. Precipitable Water • In an element dz, the mass of water vapor is dmp • Integrate over the whole atmospheric column to get precipitable water,mp • mp/A gives precipitable water per unit area in kg/m2 2 Column Element, dz Area = A 1

  32. Precipitable Water, Jan 2003

  33. Precipitable Water, July 2003

  34. January July

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