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Premium member Presentation Transcript Biosphere/Atmosphere Interactions Biology 164/264: Biosphere/Atmosphere Interactions Biology 164/264 2007 Joe Berry joeberry@globalecology.stanford.edu Chris Field cfield@globalecology.stanford.edu Adam Wolf adamwolf@stanford.edu Basic questions to be addressed by this course:: Basic questions to be addressed by this course: What are the major fluxes of energy and matter between the atmosphere and land ecosystems? What determines the temperature of leaves, plants, soils, and ecosystems? What controls rates of plant photosynthesis and transpiration? How do atmospheric processes interact with ecosystem processes to control CO2 and water exchanges? How do characteristics of the land surface influence the motions of the atmosphere? How do characteristics of the land surface influence climate? How do greenhouse gases exchanged by ecosystems influence climate? How can we measure and model the exchanges of matter and energy from the leaf to the global scale?Mechanics: Mechanics 2 lectures per week – TTh 11-11:50 Bio T 185 1 lab per week – Tuesday 2-5 Carnegie Global Ecology (260 Panama Street) 1 optional Matlab/problem session – Thursday 4-6 Carnegie Global Ecology (260 Panama Street) Grading: Bio 164: Weekly problem/program 60% Final project data analysis 20% Class participation 10% Labs (weekly data sets) 10% Bio 264: Weekly problem/program 40% Final integrated program 20% Final project data analysis 20% Class participation 10% Labs (weekly data sets) 10% Problem/programs in Matlab No midterm, no final, no papersLabs: Labs January 16 Principles of environmental sensors & data loggers Radiation sensors January 23 Environmental sensors – wind, humidity, soil moisture, water potential January 30 Environmental sensors – CO2, water vapor February 6 Leaf gas exchange February 13 Leaves – fluorescence, spectral reflectance, isotope exchange February 20 Canopy gas exchange – eddy flux hardware February 27 Canopy gas exchange – environmental conditions at an eddy flux installation March 6 Canopy gas exchange – vegetation status and fluxes at an eddy flux installation March 13 Canopy gas exchange – setting up an eddy flux system For each lab, each pair will be responsible for collecting, analyzing, and turning in a data set collected from at least one sensor or systemTexts: Texts Campbell, G. S. and J. M. Norman. 1998. An Introduction to Environmental Biophysics. Springer, New York. 286 pp. (core) Hartmann, D. L. 1994. Global Physical Climatology. Academic Press, San Diego. 411 pp. (optional) Stull, R. B. 2000. Meteorology for Scientists and Engineers. Brooks Cole, Pacific Grove. 503 pp. (optional) Bonan, G. B. 2002. Ecological climatology: Concepts and applications. Cambridge University Press, New York. 678 pp. (optional)What sets the temperature of objects and ecosystems?: What sets the temperature of objects and ecosystems?Slide7: Heat-trapping or greenhouse gases trap thermal radiation on its way to space. Energy in = Energy out + storage What controls the temperature of the planet?What controls rates of photosynthesis?: What controls rates of photosynthesis? Photosynthetic capacity Leaf nitrogen Evergreen sclerophylls Deciduous trees Annual weedsHow do plants cope with extreme environments?: How do plants cope with extreme environments?What controls the carbon balance of ecosystems?: What controls the carbon balance of ecosystems? What controls the movements of the atmosphere?: What controls the movements of the atmosphere?How do ecosystems influence climate? : How do ecosystems influence climate? Radiation: Radiation All objects at temperatures above absolute zero emit radiation. Photons carry a unique amount of energy that depends on wavelength E = hc/l Where h is Planck’s constant (6.63*10-34 Js), c is the speed of light (3*1010m s-1), and l is wavelength (m).Thermal Radiation: Thermal Radiation Stephan-Boltzmann Law s = 5.67 * 10-8 W m-2 K-4 Earth approximates a black body at 288 K -- Emits 390 W m-2 Black body = emissivity () = 1 Note: the emissivity of plants is close to 1, but other objects can have very different valuesAbsorptance and Emissivity: Absorptance and Emissivity Absorbed radition is proportional to absorptance Emitted radiation in proportional to emissivity = absorptanceBlackbody radiation: Blackbody radiation Amount increases with T4 Wavelength of maximum proportional to 1/TWien Law: Wien Law objects at 300k maximum emission at about 10 micrometersSolar energy: Solar energy Solar output 3.84*1034 W extra-atmosphere – the sun is close to a 5760 K black body radiant emittance = 6.244*107 W m-2 most of the solar energy is in the range of 0.3 – 2.5 micrometers about 50% is visible (0.4 – 0.7m) and about 50% is infrared (> 0.7m) The solar (not so) constant Integrating this emittance over the size of the sun and the distance to the earth leads to a radiation at the outside of the atmosphere of 1360 W m-2 Integrating over the spherical surface leads to an average radiation of about 342 W m-2The solar spectrum: The solar spectrumAtmospheric transmission: Atmospheric transmission Absorption Average absorption by the atmosphere 62 W m-2 Scattering Raleigh (small particle) – shortest wavelengths scattered preferentially out of the solar beam Mie (large particle) – little wavelength dependence Average reflected solar radiation by the atmosphere 77 W m-2 Effects of clouds Scattering and reflectance The greenhouse effect Increased absorptance of thermal radiation means increased radiation directed back to the surface Increased absorptance in the atm effectively increases the height at which the atmosphere is radiating back to space Atmospheric absorption: Atmospheric absorptionThe cosine law: The cosine lawSpatial distribution of solar energy: Spatial distribution of solar energy You do not have the permission to view this presentation. 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intro january 9 Heather Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINTLite Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 49 Category: Entertainment License: All Rights Reserved Like it (0) Dislike it (0) Added: October 22, 2007 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript Biosphere/Atmosphere Interactions Biology 164/264: Biosphere/Atmosphere Interactions Biology 164/264 2007 Joe Berry joeberry@globalecology.stanford.edu Chris Field cfield@globalecology.stanford.edu Adam Wolf adamwolf@stanford.edu Basic questions to be addressed by this course:: Basic questions to be addressed by this course: What are the major fluxes of energy and matter between the atmosphere and land ecosystems? What determines the temperature of leaves, plants, soils, and ecosystems? What controls rates of plant photosynthesis and transpiration? How do atmospheric processes interact with ecosystem processes to control CO2 and water exchanges? How do characteristics of the land surface influence the motions of the atmosphere? How do characteristics of the land surface influence climate? How do greenhouse gases exchanged by ecosystems influence climate? How can we measure and model the exchanges of matter and energy from the leaf to the global scale?Mechanics: Mechanics 2 lectures per week – TTh 11-11:50 Bio T 185 1 lab per week – Tuesday 2-5 Carnegie Global Ecology (260 Panama Street) 1 optional Matlab/problem session – Thursday 4-6 Carnegie Global Ecology (260 Panama Street) Grading: Bio 164: Weekly problem/program 60% Final project data analysis 20% Class participation 10% Labs (weekly data sets) 10% Bio 264: Weekly problem/program 40% Final integrated program 20% Final project data analysis 20% Class participation 10% Labs (weekly data sets) 10% Problem/programs in Matlab No midterm, no final, no papersLabs: Labs January 16 Principles of environmental sensors & data loggers Radiation sensors January 23 Environmental sensors – wind, humidity, soil moisture, water potential January 30 Environmental sensors – CO2, water vapor February 6 Leaf gas exchange February 13 Leaves – fluorescence, spectral reflectance, isotope exchange February 20 Canopy gas exchange – eddy flux hardware February 27 Canopy gas exchange – environmental conditions at an eddy flux installation March 6 Canopy gas exchange – vegetation status and fluxes at an eddy flux installation March 13 Canopy gas exchange – setting up an eddy flux system For each lab, each pair will be responsible for collecting, analyzing, and turning in a data set collected from at least one sensor or systemTexts: Texts Campbell, G. S. and J. M. Norman. 1998. An Introduction to Environmental Biophysics. Springer, New York. 286 pp. (core) Hartmann, D. L. 1994. Global Physical Climatology. Academic Press, San Diego. 411 pp. (optional) Stull, R. B. 2000. Meteorology for Scientists and Engineers. Brooks Cole, Pacific Grove. 503 pp. (optional) Bonan, G. B. 2002. Ecological climatology: Concepts and applications. Cambridge University Press, New York. 678 pp. (optional)What sets the temperature of objects and ecosystems?: What sets the temperature of objects and ecosystems?Slide7: Heat-trapping or greenhouse gases trap thermal radiation on its way to space. Energy in = Energy out + storage What controls the temperature of the planet?What controls rates of photosynthesis?: What controls rates of photosynthesis? Photosynthetic capacity Leaf nitrogen Evergreen sclerophylls Deciduous trees Annual weedsHow do plants cope with extreme environments?: How do plants cope with extreme environments?What controls the carbon balance of ecosystems?: What controls the carbon balance of ecosystems? What controls the movements of the atmosphere?: What controls the movements of the atmosphere?How do ecosystems influence climate? : How do ecosystems influence climate? Radiation: Radiation All objects at temperatures above absolute zero emit radiation. Photons carry a unique amount of energy that depends on wavelength E = hc/l Where h is Planck’s constant (6.63*10-34 Js), c is the speed of light (3*1010m s-1), and l is wavelength (m).Thermal Radiation: Thermal Radiation Stephan-Boltzmann Law s = 5.67 * 10-8 W m-2 K-4 Earth approximates a black body at 288 K -- Emits 390 W m-2 Black body = emissivity () = 1 Note: the emissivity of plants is close to 1, but other objects can have very different valuesAbsorptance and Emissivity: Absorptance and Emissivity Absorbed radition is proportional to absorptance Emitted radiation in proportional to emissivity = absorptanceBlackbody radiation: Blackbody radiation Amount increases with T4 Wavelength of maximum proportional to 1/TWien Law: Wien Law objects at 300k maximum emission at about 10 micrometersSolar energy: Solar energy Solar output 3.84*1034 W extra-atmosphere – the sun is close to a 5760 K black body radiant emittance = 6.244*107 W m-2 most of the solar energy is in the range of 0.3 – 2.5 micrometers about 50% is visible (0.4 – 0.7m) and about 50% is infrared (> 0.7m) The solar (not so) constant Integrating this emittance over the size of the sun and the distance to the earth leads to a radiation at the outside of the atmosphere of 1360 W m-2 Integrating over the spherical surface leads to an average radiation of about 342 W m-2The solar spectrum: The solar spectrumAtmospheric transmission: Atmospheric transmission Absorption Average absorption by the atmosphere 62 W m-2 Scattering Raleigh (small particle) – shortest wavelengths scattered preferentially out of the solar beam Mie (large particle) – little wavelength dependence Average reflected solar radiation by the atmosphere 77 W m-2 Effects of clouds Scattering and reflectance The greenhouse effect Increased absorptance of thermal radiation means increased radiation directed back to the surface Increased absorptance in the atm effectively increases the height at which the atmosphere is radiating back to space Atmospheric absorption: Atmospheric absorptionThe cosine law: The cosine lawSpatial distribution of solar energy: Spatial distribution of solar energy