Disentangling chlorophyll fluorescence from atmospheric scattering effects in O2 A-band spectra of reflected sun-light

Disentangling chlorophyll fluorescence from atmospheric scattering effects in O2 A-band spectra of reflected sun-light

Global retrieval of solar induced fluorescence emitted by terrestrial vegetation can provide an unprecedented measure for photosynthetic efficiency. The GOSAT (JAXA, launched Feb. 2009) and OCO‐2 (NASA, to be launched 2013) satellites record high‐resolution spectra in the O2 A‐band region, overlappi...

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Bibliographic Details
Published in:Geophysical research letters Vol. 38; no. 3
Main Authors: Frankenberg, C., Butz, A., Toon, G. C.
Format: Journal Article
Language:English
Published: Washington, DC Blackwell Publishing Ltd 01-02-2011
American Geophysical Union
John Wiley & Sons, Inc
Subjects:
aerosol retrieval
Aerosols
Albedo
Atmospheric aerosols
Atmospheric sciences
Chlorophyll
chlorophyll fluorescence
Climate change
Earth
Earth sciences
Earth, ocean, space
Exact sciences and technology
Fluorescence
Geobiology
GOSAT
O2 A-band
OCO
Remote sensing
Fluorescence spectrum
efficiency
aerosols
NASA
Bias
Space remote sensing
chlorophyll
Satellite observation
vegetation
least-squares
global
Sun
greenhouse gas
Absorption line
optical properties
fluorescence
s parameter
Surface pressure
Optical thickness
Fraunhofer line
albedo
high resolution
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Summary:Global retrieval of solar induced fluorescence emitted by terrestrial vegetation can provide an unprecedented measure for photosynthetic efficiency. The GOSAT (JAXA, launched Feb. 2009) and OCO‐2 (NASA, to be launched 2013) satellites record high‐resolution spectra in the O2 A‐band region, overlapping part of the chlorophyll fluorescence spectrum. We show that fluorescence cannot be unambiguously discriminated from atmospheric scattering effects using O2 absorption lines. This can cause systematic biases in retrieved scattering parameters (aerosol optical thickness, aerosol height, surface pressure, surface albedo) if fluorescence is neglected. Hence, we demonstrate an efficient alternative fluorescence least‐squares retrieval method based solely on strong Fraunhofer lines in the vicinity of the O2 A‐band, disentangling fluorescence from scattering effects. Not only does the Fraunhofer line fit produce a more accurate estimate of fluorescence emission, but it also allows improved retrievals of atmospheric aerosols from the O2 A‐band.
Bibliography:istex:D58D033FDCB8B86BE3FD5DE584F51805E17CB56F
ark:/67375/WNG-Z17NF9TG-X
ArticleID:2010GL045896
ISSN:0094-8276
1944-8007
DOI:10.1029/2010GL045896