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'''Ångström exponent''' is the name of the exponent in the formula that is usually used to describe the dependency of the [[aerosol]] [[optical thickness]], or aerosol [[refractive index#Dispersion and absorption|extinction coefficient]] on [[wavelength]].
 
Depending on particle size distribution, the spectral dependence of the aerosol optical thickness is given approximately by
 
:<math>\frac{\tau_\lambda}{\tau_{\lambda_0}}=\left (\frac{\lambda}{\lambda_0}\right )^{-\alpha}</math>
 
where <math>\tau_\lambda</math> is the optical thickness at wavelength <math>\lambda</math>, and <math>\tau_{\lambda_0}</math> is the optical thickness at the reference wavelength <math>\lambda_0</math>. In principle, if the optical thickness at one wavelength and the Ångström exponent are known, the optical thickness can be computed at a different wavelength. In practice, measurements are made of the optical thickness of an aerosol layer at two different wavelengths, and the Ångström exponent is estimated from these measurements using this formula. The aerosol optical thickness can then be derived at all other wavelengths, within the range of validity of this formula.
 
For measurements of optical thickness <math>\tau_{\lambda_1}\,</math> and <math>\tau_{\lambda_2}\,</math> taken at two different wavelengths <math>\lambda_1\,</math> and <math>\lambda_2\,</math> respectively, the Ångström exponent is given by
 
:<math>\alpha = - \frac{\log \frac{\tau_{\lambda_1}}{\tau_{\lambda_2}}}{\log \frac{\lambda_1}{\lambda_2}}\,</math>
 
The Ångström exponent is inversely related to the average size of the particles in the aerosol: the smaller the particles, the larger the exponent. Thus, Ångström exponent is a useful quantity to assess the particle size of atmospheric aerosols or clouds, and the wavelength dependence of the aerosol/cloud optical properties. For example, cloud droplet, usually with large sizes and thus very smaller Ångström exponent (nearly zero), is spectrally neutral, which means, e.g., the optical depth does not change with wavelength. This exponent is now routinely estimated by analyzing radiation measurements acquired on [[Earth observation|Earth Observation]] platforms, such as [[AErosol RObotic NETwork]], or [[AERONET]].
 
==See also==
 
{{Empty section|date=July 2010}}
==References==
{{reflist}}
* [http://www.grida.no/climate/ipcc_tar/ IPCC Third Assessment Report, has extensive coverage of aerosol-climate interactions].
 
* Kuo-nan Liou (2002) ''An Introduction to Atmospheric Radiation'', International Geophysics Series, No. 84, Academic Press, 583 p, ISBN 0-12-451451-0.
 
==External links==
* [http://daac.gsfc.nasa.gov/PIP/shtml/aerosol_angstrom_exponent.shtml Angstrom coefficient page at NASA GSFC].
* [http://aeronet.gsfc.nasa.gov/ AERONET: an international network of sunphotometers measuring aerosol properties].
* [http://photojournal.jpl.nasa.gov/catalog/PIA04382 Spatial distributions of the Angstrom coefficient as derived from [[MISR]]].
 
[[Category:Scattering, absorption and radiative transfer (optics)]]
[[Category:Atmospheric radiation]]
[[Category:Visibility]]

Revision as of 03:36, 13 November 2013

Ångström exponent is the name of the exponent in the formula that is usually used to describe the dependency of the aerosol optical thickness, or aerosol extinction coefficient on wavelength.

Depending on particle size distribution, the spectral dependence of the aerosol optical thickness is given approximately by

τλτλ0=(λλ0)α

where τλ is the optical thickness at wavelength λ, and τλ0 is the optical thickness at the reference wavelength λ0. In principle, if the optical thickness at one wavelength and the Ångström exponent are known, the optical thickness can be computed at a different wavelength. In practice, measurements are made of the optical thickness of an aerosol layer at two different wavelengths, and the Ångström exponent is estimated from these measurements using this formula. The aerosol optical thickness can then be derived at all other wavelengths, within the range of validity of this formula.

For measurements of optical thickness τλ1 and τλ2 taken at two different wavelengths λ1 and λ2 respectively, the Ångström exponent is given by

α=logτλ1τλ2logλ1λ2

The Ångström exponent is inversely related to the average size of the particles in the aerosol: the smaller the particles, the larger the exponent. Thus, Ångström exponent is a useful quantity to assess the particle size of atmospheric aerosols or clouds, and the wavelength dependence of the aerosol/cloud optical properties. For example, cloud droplet, usually with large sizes and thus very smaller Ångström exponent (nearly zero), is spectrally neutral, which means, e.g., the optical depth does not change with wavelength. This exponent is now routinely estimated by analyzing radiation measurements acquired on Earth Observation platforms, such as AErosol RObotic NETwork, or AERONET.

See also

Template:Empty section

References

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  • Kuo-nan Liou (2002) An Introduction to Atmospheric Radiation, International Geophysics Series, No. 84, Academic Press, 583 p, ISBN 0-12-451451-0.

External links