1 / 22

The solar spectrum compared to a black body

The solar spectrum compared to a black body. Blackbody radiation curves typical for the Sun and Earth. Sun ~6000K. Earth ~290K. Sun radiates a lot more energy that the Earth!. Normalized blackbody radiation curves for Earth and Sun. Divide each radiation curve by its maximum value

sheng
Download Presentation

The solar spectrum compared to a black body

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. The solar spectrum compared to a black body

  2. Blackbody radiation curves typical for the Sun and Earth Sun ~6000K Earth ~290K Sun radiates a lot more energy that the Earth!

  3. Normalized blackbody radiation curves for Earth and Sun • Divide each radiation curve by its maximum value • to normalize curves: • Very little overlap of the normalized radiation curves

  4. How steady is the Sun’s output? • Measurements of solar radiation from space, • rockets, and balloons • Note on short timescales, some large fluctuations are possible. C. FRÖHLICH IPCC, 2001

  5. Solar variability: the sunspot cycle

  6. Reconstructions of solar variability over time TSI = total solar irradiance Note the scientific trend too… IPCC, 2001

  7. How do we get these temperatures? -Infrared temperatures from Aqua satellite, April 2003.

  8. Reflectivity (albedo) of Solar (shortwave) radiation September, 2005 smsc.cnes.fr/IcPARASOL Global average ~30% Albedo increases with latitude Oceans are quite dark (low reflectivity)

  9. Emissivity of infrared radiation at the surface cimss.ssec.wisc.edu/iremis/ Emissivity, e, is a measure of how well blackbody radiation is obeyed: F=esT4 Emissivity/absorptivity is close to 1. This implies a good approximation to black body in the infrared

  10. Summary (important)- At visible wavelengths, the Earth reflects about 30% of the incident radiation. At infrared wavelengths, most natural materials absorb almost Everything (~95 to 98%), so the Earth behaves quite closely as a true blackbody. -Go to calculation of black body temperature

  11. Radiation and physical objects Any physical material (solid, liquid, gas) interacts with electromagnetic waves (radiation) in one of four different ways. TRANSMISSION: waves pass through the material ABSORPTION: some of the waves are absorbed (& heat) REFLECTION: some of the waves are reflected in the direction they came from. EMISSION: Every object (above absolute zero) emits radiation because it possesses thermal energy Less important:- SCATTERING: waves are deflected (hence blue sky…)

  12. Radiation and physical objects How a material interacts with radiation (transmission, absorption, emission, reflection) depends on what it is made of. For example: what’s the difference between the yellow light in these 3 pictures?

  13. A key fact for Earth’s climate is that gases in the atmosphere absorb radiation. • Molecules absorb radiation at particular wavelengths, depending on amount of energy required to cause vibration or rotation of atomic bond. • Two essential things for the greenhouse effect: • The Earth’s atmosphere is mostly transparent to visible radiation (why not totally) • The Earth’s atmosphere is mostly opaque to infrared radiation.

  14. The composition of the Earth’s atmosphere matters... (Plus other trace components, e.g. methane, CFCs, ozone) • Bi-atomic molecules (O2, N2) can only absorb • high energy photons, meaning ultraviolet • wavelengths and shorter. • Tri-atomic molecules (H2O, CO2) can absorb • lower energy photons, with wavelengths in the • infrared

  15. Atmospheric absoption by atmospheric constituents solar & terrestrial emissions as a function of wavelength 100%- CH4 N20 O2,03 CO2 H20 0%- Peixoto and Oort, 1992

  16. Key things from previous slide:- • Atmosphere mostly transparent to solar radiation (except in uv) • Atmosphere mostly opaque to terrestrial radiation (infrared) • Water vapor is the most important greenhouse gas (by far) • Carbon dioxide is a problem because of a ‘window’ in H2O • absorption spectrum. • This physics is very, very well known

  17. Atmospheric absorption • Shortwave (i.e. solar) radiation measured from the top of • atmosphere and from the ground. • The (clear) atmosphere is not totally • transparent to solar radiation: • back scatter by dust, aerosols • absorption by constituent gases • amount varies as a function of • wavelength Peixoto and Oort, 1992

  18. Energy pathways in the atmosphere IPCC, 2007

  19. This is wrong – why?

  20. Greenhouse effect summary • CO2 and H20 (and some other gasses) effectively absorb radiation at the same wavelengths that the Earth • emits at. • Some of that radiation is then re-emitted back towards the ground keeping the surface warmer than it would otherwise be. Essential to remember: - CO2 , H20 in the atmosphere absorbs and re-emits infrared radiation - It does NOT (not, not, not) reflect radiation

More Related