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HOW DOES ENERGY ESCAPE THE PLANETARY SYSTEM?. The Outgoing Longwave Radiation Balance. Space. Atmosphere. 20. Surface. 49. 69 Back to Space as longwave. Space. Atmosphere. 20. Surface. 49. 69 Back to Space as longwave. Space. Atmosphere. 20. 7. Surface. 49. Convection.
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HOW DOES ENERGY ESCAPETHE PLANETARY SYSTEM? The Outgoing Longwave Radiation Balance
Space Atmosphere 20 Surface 49
69 Back to Space as longwave Space Atmosphere 20 Surface 49
69 Back to Space as longwave Space Atmosphere 20 7 Surface 49 Convection
69 Back to Space as longwave Space Atmosphere 20 50 = 7 + 23 + 20 7 23 Surface 49 Latent Heat Convection
Direct OLR 12 + ??? = 69 Back to Space as longwave Space 12 Atmosphere Greenhouse Gases 20 50 = 7 + 23 + 20 7 12 23 Surface 49 Latent Heat Convection Outgoing Longwave Radiation
Direct OLR 12 + ??? = 69 Back to Space as longwave Space 12 Atmosphere Greenhouse Gases 20 50 = 7 + 23 + 20 Absorb 7 102 12 23 Surface 49 Latent Heat Convection Outgoing Longwave Radiation
Direct OLR 12 + ??? = 69 Back to Space as longwave Space 12 Cooler Atmosphere Greenhouse Gases 20 Re-emit 50 = 7 + 23 + 20 Absorb Warmer 7 102 12 23 Surface 49 Latent Heat Convection Outgoing Longwave Radiation
Direct OLR 12 + ??? = 69 Back to Space as longwave Space 12 Cooler Atmosphere Greenhouse Gases 20 Re-emit 50 = 7 + 23 + 20 Absorb Warmer 7 102 12 23 Surface 49 Latent Heat Convection Outgoing Longwave Radiation
Direct OLR 12 + ??? = 69 Back to Space as longwave Space 12 Atmosphere Greenhouse Gases 20 Re-emit 50 = 7 + 23 + 20 Absorb Warmer 95 7 102 12 23 Surface 49 Latent Heat Convection Outgoing Longwave Radiation
Direct OLR 12 + ??? = 69 Back to Space as longwave Space 12 Cooler Atmosphere Greenhouse Gases 20 Re-emit 50 = 7 + 23 + 20 102 - 95 = 7 Absorb Warmer 95 7 102 12 23 Surface 49 Latent Heat Convection Outgoing Longwave Radiation
Direct OLR Indirect OLR 12 + ??? = 69 Back to Space as longwave Space 57 12 Cooler Atmosphere Greenhouse Gases 20 Re-emit 50 = 7 + 23 + 20 102 - 95 = 7 Absorb Warmer 95 7 102 12 23 Surface 49 Latent Heat Convection Outgoing Longwave Radiation
Direct OLR Indirect OLR 12 + 57 = 69 Back to Space as longwave Space 57 12 Cooler Atmosphere Greenhouse Gases 20 Re-emit 50 = 7 + 23 + 20 102 - 95 = 7 Absorb Warmer 95 7 102 12 23 Surface 49 Latent Heat Convection Outgoing Longwave Radiation
RESEARCH AND PRACTICAL APPLICATION Yatir Reforestation, Israel 2004 - 2009 E. Rotenberg et al., Science 327, 451-454 (2010)
More reflection Less total energy Cooler? Less reflection More total energy Hotter?
(In) (Out) ? Insolation = 238Wm-2 (69% of 345Wm-2) E. Rotenberg et al., Science 327, 451-454 (2010) Published by AAAS
Wait a minute! More radiation in, but less out! (In) (Out) ? Insolation = 238Wm-2 (69% of 345Wm-2) E. Rotenberg et al., Science 327, 451-454 (2010) Published by AAAS
(In) (Out) ? Insolation = 238Wm-2 (69% of 345Wm-2) E. Rotenberg et al., Science 327, 451-454 (2010) Published by AAAS
(In) (Out) ? Insolation = 238Wm-2 (69% of 345Wm-2) E. Rotenberg et al., Science 327, 451-454 (2010) Published by AAAS
238 Wm-2 Reforestation Desert Scrub
238 Wm-2 Albedo = 10% Albedo = 21%
238 Wm-2 Albedo = 10% Albedo = 21% Net Radiation 212 Wm-2 Net Radiation 188 Wm-2
238 Wm-2 Strong vertical layering discourages movement of energy away from surface. Increased Upward Turbulent Cooling SENSIBLE HEAT + LATENT HEAT Albedo = 10% Albedo = 21% Net Radiation 188 Wm-2 Net Radiation 212 Wm-2
238 Wm-2 Strong vertical layering discourages movement of energy away from surface. Increased Upward Turbulent Cooling Less need for longwave (96) transfer Energy must be lost by longwave (121) requires high surface temps Albedo = 10% Albedo = 21% Net Radiation 188 Wm-2 Net Radiation 212 Wm-2
238 Wm-2 Strong vertical layering discourages movement of energy away from surface. Increased Upward Turbulent Cooling Less need for longwave (96) transfer Energy must be lost by longwave (121) requires high surface temps Albedo = 10% Temp = 19°C Temp = 27°C Albedo = 21% Net Radiation 188 Wm-2 Net Radiation 212 Wm-2