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Sediments of the Tay Estuary. VI. Sediments of the lower and outer reaches

Published online by Cambridge University Press:  05 December 2011

J. McManus ,
A. T. Buller  and
C. D. Green
J. McManus
Affiliation:
Department of Geology, University of Dundee
A. T. Buller
Affiliation:
Tay Estuary Research Centre, Dundee
C. D. Green
Affiliation:
Tay Estuary Research Centre, Dundee
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Synopsis

The main channels converge at Dundee and form a single outlet passing seawards of the Broughty Ferry-Tayport constriction. The coarsest sediments, often of gravels and shell debris, line the floor of the channel, which is locally cut into late-glacial marine clays. Extensive sandy tidal flats seaward of the constriction pass eastwards into dune-covered sand spits pointing into the North Sea. The entrance bar has a delta-like form which is slowly overriding the fine sands of the North Sea floor.

The median, sorting, and skewness of the sediments, and the covariation of several parameters follow patterns readily related to the physiographic features of the estuary.

Many of the beach and tidal flat areas are in a constant state of change, and repeated topographic surveying reveals the magnitude of these changes on a short time scale. The changes in sediment characteristics demonstrated by repeated sampling and analysis of material from one stretch of Broughty Ferry beach are substantial. Size-frequency distribution plots indicate that up to four sub-populations of grains are present. Natural combinations of these in different proportions produce systematic variations in values of the normally used sediment characterising statistics.

Type
Research Article
Information
Proceedings of the Royal Society of Edinburgh, Section B: Biological Sciences , Volume 78 , Issue 3-4 , 1980 , pp. s133 - s153
Copyright
Copyright © Royal Society of Edinburgh 1980

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References

Bascom, W. N., 1951. The relationship between sand size and beach face slope. Trans. Am. Geophys. Un., 32, 866874.Google Scholar
Buller, A. T. and McManus., J., 1972. Simple metric sedimentary statistics used to recognise different environments. Sedimentology, 18, 121.Google Scholar
Buller, A. T. and McManus, J., 1973. The quartile-deviation/median diameter relationship of glacial deposits. Sediment. Geol, 10, 135146.CrossRefGoogle Scholar
Buller, A. T. and McManus, J., 1975. Sediments of the Tay Estuary. 1. Bottom sediments of the Upper and Upper Middle Reaches. Proc. Roy. Soc. Edinb., 75B, 4164.Google Scholar
Buller, A. T., Green, C. D. and McManus, J., 1975. Dynamics and sedimentation: The Tay in comparison with other estuaries. In Hails, J. R. and Carr, A. (eds) Nearshore Sediment Dynamics, 201249. London:Wiley.Google Scholar
Crawford, R. M., 1965. A multi-vanale analysis of the development of dune slack vegetation in relation to coastal accretion at Tentsmuir, Fife. J. Ecol., 54, 729743.CrossRefGoogle Scholar
Darling, J. M., 1964. Seasonal changes in beaches of the North Atlantic coast of the United States. Proc. 9th Conf. Coastal Engng, 236–248.CrossRefGoogle Scholar
Doeglas, D. J., 1971. Q1MdQ3 indices showing grain-size distribution on maps. Geologie Mijnb., 50, 367372.Google Scholar
Drysdale, W. S., 1956. Firth of Forth Seismic Refraction Survey. Trans. Instn Min. Engrs, 115, 435454Google Scholar
Folk, R. L., 1966. A review of grain-size parameters. Sedimentology, 6, 7393.Google Scholar
Folk, R. L. & Ward, W.C., 1957. Brazos River bar, a study in the significance of grain size parameters. J. Sedim. Petrol, 27, 327.CrossRefGoogle Scholar
Gorsline, D. S., 1966. Dynamic characteristics of West Florida Gulf coast beaches. Mar. Geol., 4,187206.CrossRefGoogle Scholar
Gorsline, D. S. & Grant, D. J., 1972. Sediment textural patterns on San Pedro Shelf, California (19511971). Reworking and Transport by Waves and Currents. In Swift,D. S., Duane, D. B. and Pilkey, O. B. (eds) Shelf Sediment Transport. Stroudsburg, Pa.: Dowden Hutchinson & Ross.Google Scholar
Green, C. D., 1974. Sedimentary and morphological dynamics between St. Andrews Bay and Tayport, Tay Estuary, Scotland. Unpubl. Ph.D. Thesis, Univ. Dundee.Google Scholar
Green, C. D., 1975. Sediments of the Tay Estuary. III. Sedimentological and faunal relationships on the southern shore at the entrance to the Tay. Proc. Roy. Soc. Edinb., 75B, 91112.Google Scholar
Green, C. D., 1976. A study of hydraulics and bedforms at the mouth of the Tay estuary, Scotland. In Estuarine Research, 212221. Myrtle Beach: Estuarine Research Federation.Google Scholar
Gresswell, R. F., 1937. The geomorphology of the south-west Lancashire coastline. Geogrl J., 90,335348.CrossRefGoogle Scholar
Griffiths, J.C., 1967. Scientific method in the Analysis of Sediments. New York: McGraw-Hill.Google Scholar
Ingle, J.C., 1966. The movement of beach sand. Amsterdam: Elsevier.Google Scholar
Inman, D. S., 1952. Measures for describing the size distributions of sediments. J. Sedim. Petrol., 22, 125145.Google Scholar
King, C. A. M., 1972. Beaches & Coasts, 2nd edn. London: Edward Arnold.Google Scholar
Krumbein, W.C., 1936. The use of quartile measures in describing and comparing sediments. Am. J. Sci., 37, 98–11.CrossRefGoogle Scholar
Lewis, W. V., 1931. The effect of wave incidence on the configuration of a shingle beach. Geogrl J., 78, 129148.CrossRefGoogle Scholar
McManus, J., 1966. Bottom structures of the Tay and other estuaries. Scott. Geogr. mag., 82, 192197.Google Scholar
McManus, J., 1967. Pre-glacial diversion of the Tay drainage through the Perth gap. Scott. Geogr. Mag., 83, 138139.Google Scholar
McManus, J., 1972. Estuarine development and sediment distribution with particular reference to the Tay. Proc. Roy. Soc. Edinb., 71B, 97113.Google Scholar
Mishra, S. K., 1969. Heavy mineral studies of the Firth of Tay region, Scotland. J. Geol. Soc. Univ. Saugar, 5, 3749.Google Scholar
Pugh, D.C., 1953. Etudes mineralogiques des plages Picardes et Flammandes. Bull. Ingrs Com. Cent Oceanog. Etudes Côves, 5, 254276.Google Scholar
Shepard, F. P., 1950. Longshore bars and longshore troughs. Beach Erosion Board. Tech. Memo. 15.Google Scholar
Smith, D. E., Sissons, J. B. and Cullingford, R. A., 1969. Isobases for the main Perth Raised Shoreline in south-east Scotland as determined by trend-surface analysis. Trans. Inst. Br. Geogr., 46, 4552.CrossRefGoogle Scholar
Strahler, A. N., 1966. Tidal cycle of changes on an equilibrium beach. J. Geol., 74, 247268.Google Scholar
Thomson, M. E., 1978. IGS studies of the Firth of Forth and its approaches. I.G.S. Report 7717.Google Scholar
Trask, P. D., 1930. Mechanical analysis of sediment by centrifuge. Econ. Geol., 25, 581599.Google Scholar
Trask, P. D., 1932. Origin and Environment of source sediments of Petroleum. Houston, Texas: Gulf.Google Scholar
Visher, G. S., 1969, Grain size distributions and depositional processes. J. Sedim. Petrol., 39, 10741106.Google Scholar
Williams, D. J. A. & West, J. R., 1975. Salinity distribution in the Tay Estuary. Proc. Roy. Soc. Edinb., 75B, 2939.Google Scholar