Abstract
In mainland Australia and in southern Africa, the aridity of the climate and sparse vegetative cover increase the susceptibility of the soils to erosion, and as a consequence surface waters are usually turbid. The inanimate suspensoids in such waters, the ‘tripton’ fraction of the limnologist, are responsible for virtually all the light scattering, and also, by virtue of the yellow-brown humic materials adsorbed on their surface, for a substantial part of the light absorption. Spectral absorption data for suspensoids in terms of theirin situ absorption coefficient values, and the contribution of suspensoids to absorption of photosynthetically available radiation (PAR) are given for certain Australian water bodies.
To understand the effect of suspensoids on attenuation of the solar flux with depth, the scattering coefficient must also be known, and this can be determined from the nephelometric turbidity or from up- and down-welling irradiance measurements. The effect of particle size on scattering efficiency is discussed.
An equation expressing the vertical attenuation coefficient for downward irradiance as a function of absorption coefficient, scattering coefficient and solar altitude is presented, and is used to explore the effects of absorption due to dissolved colour and suspensoids, and the effects of scattering by suspensoids, on the penetration of PAR.
Suspensoids, by increasing the rate of attenuation of the solar flux with depth, can greatly diminish the euphotic depth of a water body, with a consequent decrease in the ratio of the euphotic to the mixed depth: thus turbidity can reduce productivity of a water body substantially below that which might be expected on the basis of nutrient availability. Shallow turbid waters of low intrinsic colour can, however, be highly productive. By diminishing the depth of the layer within which solar energy is dissipated as heat, suspensoids can greatly modify the hydrodynamic behaviour of water bodies, and this also has far-reaching ecological consequences.
Suspensoids drastically impair the visual clarity of water, a fact of major significance for the aquatic fauna, as well of aesthetic significance for humanity. The reciprocal of the Secchi depth is more correctly thought of as a guide to the vertical contrast attenuation coefficient rather than to the vertical attenuation coefficient for irradiance. The reflectivity of a water body, being at any wavelength proportional to the backscattering coefficient divided by the absorption coefficient, is highly dependent on the concentration, and optical character, of the suspensoids present. This has implications not only for the appearance (colour, muddiness) of the water to an observer, but also for the remote sensing of water composition by air- or satellite-borne radiometric sensors.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Austin, R. W. & T. J. Petzold, 1977. Considerations in the design and evaluation of oceanographic transmissometers. In J. Tyler (ed.), Light in the Sea. Dowden, Hutchinson & Ross, Stroudsberg, 104–120.
Di Toro, D. M., 1978. Optics of turbid estuarine water: approximation and applications. Wat. Res. 12: 1059–1068.
Duntley, S. Q., 1963. Light in the sea. J. Opt. Soc. Am. 53: 214–233.
Gordon, H. R. & A. Y. Morel, 1983. Remote assessment of ocean colour for interpretation of satellite visible imagery. Lecture Notes on Coastal and Estuarine Studies, 4. Springer, N.Y. 114 pp.
Grobbelaar, J. U. & P. Stegmann, 1976. Biological assessment of the euphotic zone in a turbid man-made lake. Hydrobiologia 48: 263–266.
Hart, B. T., 1982. Uptake of trace metals by sediments and suspended particulates: a review. Hydrobiologia 91: 299–313.
Hergenrader, G. L. & M. J. Hammer, 1973. Eutrophication of small reservoirs in the Great Plains. In W. C. Ackermann, G. F. White & E. B. Worthington (eds), Man-made Lakes: Their Problem and Environmental Effects. Am. Geophys. Union, Washington: 560–566.
Holmes, R. W., 1970. The Secchi disk in turbid coastal waters. Limnol. Oceanogr. 15: 688–694.
Kirk, J. T. O., 1977. Use of a quanta meter to measure attenuation and underwater reflectance of photosynthetically active radiation in some inland and coastal southeastern Australian waters. Aust. J. mar. Freshwat. Res. 28: 9–21.
Kirk, J. T. O., 1979. Spectral distribution of photosynthetically active radiation in some south-eastern Australian waters. Aust. J. mar. Freshwat. Res. 30: 81–91.
Kirk, J. T. O., 1980a. Relationship between nephelometric turbidity and scattering coefficients in certain Australian waters. Aust. J. mar. Freshwat. Res. 31: 1–12.
Kirk, J. T. O., 1980b. Spectral absorption properties of natural waters: contribution of the soluble and particulate fractions to light absorption in some inland waters of southeastern Australia. Aust. J. mar. Freshwat. Res. 31: 287–296.
Kirk, J. T. O., 1981a. A Monte Carlo study of the nature of the underwater light field in, and the relationships between optical properties of, turbid yellow waters. Aust. J. mar. Freshwat. Res. 32: 517–532.
Kirk, J. T. O., 1981b. Estimation of the scattering coefficient of natural waters using underwater irradiance measurements. Aust. J. mar. Freshwat. Res. 32: 533–539.
Kirk, J. T. O., 1982. Prediction of optical water quality. In E. M. O'Loughlin & P. Cullen (eds), Prediction in Water Quality, Aust. Acad. Sci., Canberra: 307–326.
Kirk, J. T. O., 1983. Light and Photosynthesis in Aquatic Ecosystems. Cambridge Univ. Press, Cambridge. 401 pp.
Kirk, J. T. O., 1984a. Dependence of relationship between inherent and apparent optical properties of water on solar altitude. Limnol. Oceanogr. 29: 350–356.
Kirk, J. T. O., 1984b. Attenuation of solar radiation in scattering-absorbing waters: a simplified procedure for its calculation. Applied Optics 23: 3131–3139.
Oades, J. M., 1982. Colour and turbidity in water. Prediction of optical water quality. In E. M. O'Loughlin & P. Cullen (eds), Prediction in Water Quality, Aust. Acad. Sci., Canberra: 159–179.
Olive, L. J. & P. H. Walker, 1982. Processes in overland flow-erosion and production of suspended material. In E. M. O'Loughlin & P. Cullen (eds), Prediction in Water Quality, Aust. Acad. Sci. Canberra: 87–119.
Preisendorfer, R. W., 1961. Application of radiative transfer theory to light measurements in the sea. Union Geod. Geophys. Inst. Monogr. 10: 11–30.
Preisendorfer, R. W., 1976. Hydrologic Optics. v. 1. U.S. Dept. Commerce, Washington.
Spigel, R. H. & C. Howard-Williams, 1984. A method for comparing scalar irradiance measurements with upward and downward irradiance in lakes. Wat. Resources Res. 20: 507–509.
Tyler, J. E., 1968. The Secchi disc. Limnol. Oceanogr. 13: 1–6.
Van De Hulst, H. C., 1957. Light Scattering by Small Particles. Wiley, N.Y.
Walker, P. H., K. D. Woodyer & J. Hutka, 1974. Particle-size measurement by Coulter counter of very small deposits and low suspended sediment concentrations in streams. J. Sedim. Petrol. 44: 673–679.
Walmsley, R. D. & C. A. Bruwer, 1980. Water transparency characteristics of South African impoundments. J. Limnol. Soc. sth. Afr. 6: 69–76.
Walmsley, R. D., M. Butty, H. Van Der Piepen & D. Grobler, 1980. Light penetration and the interrelationships between optical parameters in a turbid subtropical impoundment. Hydrobiologia 70: 145–157.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Kirk, J.T.O. Effects of suspensoids (turbidity) on penetration of solar radiation in aquatic ecosystems. Hydrobiologia 125, 195–208 (1985). https://doi.org/10.1007/BF00045935
Issue Date:
DOI: https://doi.org/10.1007/BF00045935