919
pump and probe
scattered optical
aiding mirror is
spectral analysis
by 50 ns pulses
;nsitive both to
iduced by pump
us measurements
ire the variable
lyuk, 1994a).
■probe technique
?reen plants. As
1994), we will
;ation of laser
delay between
lyuk, 1994a).
ed the by weak
g .2 for various
Fig.3 represents
( F690 ) and 735
;he maize
intensities
s at 690 nm
he intensity
r RCs closed by
ise (Fig.2,3) in
The remarkable
ce spectra with
srence between
nm (about 2.5
(Gorbunov and
This and similar series of experiments using maize, wheat and oak leaves
have shown that the pump pulse photon flux density I on the leaf surface must
23-2-1 ^
be more than 5*10 cm s to meet the requirement (1). This value appears to
be an order of magnitude higher than that determined for algae ( 1 ^ = 10 23
quanta*cm" 2 s’ 1 ; Chekalyuk and Gorbunov, 1994).
The dependence of intensity of Chl-a fluorescence induced by probe pulse
on the delay between pump and probe pulses (see in Gorbunov and Chekalyuk,
1994a) has appeared to be similar to those obtained using lamp (Falkowski and
Kiefer, 1985) and laser excitation (Chekalyuk and Gorbunov, 1994) of algae
using pump-and-probe technique. The optimal delay between the pump and probe
pulses has been found to be 30-50 ps in the case of both algae and plant
leaves.
The most interesting results have been obtained during measuring of the
dependence of Chl-a fluorescence emission on the intensity of probe pulse I,
varying in the range of 5*10 22 to 10 24 quanta*cm‘ 2 sec _1 . The saturation of
both maximal 4> and original 4> fluorescence were observed (see Gorbunov and
m o
Chekalyuk, 1994b), but the characters of those functions were different. The
origin of this phenomenon is discussed in (Chekalyuk and Gorbunov, 1994;
Gorbunov and Chekalyuk, 1994b). The resulting value of n = ($ -4> )/$ appeared
mo in
to be also the function of I in this range. To avoid the distortions in laser
measurements of r), the photon flux density of the probe pulse on the leaf
surface must not exceed (2-3)*10 22 cm’ 2 s _1 according to our experiments.
6 . - FIELD APPLICATIONS OF LIDAR PUMP-AND-PROBE TECHNIQUE
Since the adaptation of lidar pump-and-probe technique to vegetation monitor
ing is still under development, we will focus below on its oceanographic
applications.
6 . 1 . Along-track profiling
The example of along-track high-resolution lidar monitoring of photosyn
thesis efficiency (rj = A4>/4> ) and Chl-a fluorescence is presented in Fig.4.
One can see near-zero variations of rj in the noon, caused by excessive solar
illumination in nearsurface water layer, as well as recovery of rj high levels
in the evening. Relying on night measurements, it is possible to evaluate the
BUCK SEA. April 1991
Figure 4. Along-track Lidar Monitoring of the Efficiency of Photosyn
thesis (r] = M>/4>m) and Chlorophyll-a Fluorescence (actual level $)•
