The absorption coefficient is a fundamental parameter in understanding the underwater
light field, for solving the Radiative Tranfer Equation and understanding/interpreting remotely
sensed data from the ocean. Measuring the absorption coefficient is particularly complicated in
coastal areas where the optical properties of the water body are the result of a complex mixture
of dissolved and particulate components, but mainly because of the interfering effect that
scattering has upon the measurements. A great variety of in situ instruments and laboratory
techniques have been developed to measure total absorption or the absorption by the various
fractions that constitute the total absorption. They are, however, all affected by scattering and
empirical corrections need to be applied. Among the instruments to measure absorption, a
promising one appeared to be one based on an integrating cavity. Kirk (1995, 1997) outlined the
principle and theory of an absorption meter based on an integrating sphere: a Point Source
Integrating Cavity Absorption Meter (PSICAM). He argued that owing to its design, a PSICAM
would be insensitive to scattering.
A novel Monte Carlo code was written to simulate the behaviour of a PSICAM of
various cavity radiuses. The results of the simulations carried out with this code showed that
such an absorption meter should indeed be unaffected by scattering even with high levels of
scatterers. One important disadvantage deduced from numerical modelling for a PSICAM is its
sensitivity to the reflectivity of the integrating cavity.
Several prototype PSICAMs of increasing quality were built and tested with scattering-free
standard solutions. A major difficulty in the development of the prototype was found to be
the calibration of the integrating sphere reflectivity. A final laboratory instrument made of a
Spectralon sphere was built and tested with artificial and natural water samples containing
different levels of scattering particles and compared with existing in situ and laboratory
techniques: the ac-9 transmissometer and the filter paper technique for particulate absorption as
well as measurement of Coloured Dissolved Organic Matter. Compared with the ac-9
transmissometer, the PSICAM showed remarkable agreement even for water with very high
content of Suspended Particulate Matter. Very good correlations were obtained when compared
with traditional CDOM measurement. In some cases, significant discrepancies occurred with
filter paper measurements of particulate absorption. From laboratory to in situ experiments the
PSICAM proved to be a reliable instrument assuming that the instrument was regularly and
carefully calibrated. Finally, the PSICAM was deployed during a cruise around the Antarctic
Peninsula where total and dissolved absorption measurements were carried out together with
chlorophyll absorption measurements after extraction in acetone.
Date of Award | 2003 |
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Original language | English |
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Awarding Institution | |
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DEVELOPMENT AND MODELLING OF A POINT SOURCE INTEGRATING CAVITY ABSORPTION METER (PSICAM)
LEREBOURG, C. J. J. (Author). 2003
Student thesis: PhD