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of toxicants, etc.) and species differentiation. Taking these factors into
account is of great importance for interpreting not only lidar data, but also
any other fluorescent techniques (e.g. solar-stimulated fluorescence measure
ments). The second group of factors is defined by the features of powerful
pulsed laser excitation, mostly by the saturation of Chl-a fluorescence,
caused by singlet-singlet annihilation of excitons within light-harvesting
complexes.
On the one hand, the linkage between functional state of the object and
in vivo Chl-a fluorescence complicates quantitative assessments of object
characteristics (for instance - phytoplankton Chl-a concentration in water
column or Chl-a content in leaves). On the other hand, it provides the
potentials for development of lidar techniques, capable of remote monitoring
the parameters related to physiological status of the objects and ongoing
photosynthesis, as well as bioindication of environmental impacts.
8 . - REFERENCES
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