Hostname: page-component-cd9895bd7-8ctnn Total loading time: 0 Render date: 2024-12-23T15:45:18.509Z Has data issue: false hasContentIssue false

Characteristics and significance of some humate-cemented sands (humicretes) at Cape Flattery, Queensland, Australia

Published online by Cambridge University Press:  01 May 2009

K. Pye
Affiliation:
Department of Earth Sciences, Downing Street, Cambridge CB2 3EQ, England

Summary

Humate-cemented sands (humicretes) are exposed at several locations along the foreshore and in gullies near Cape Flattery, North Queensland, Australia. Three broad types of humate accumulation are recognized: (a) pedogenetic; (b) groundwater; and (c) aquatic. Pedogenetic and groundwater humicretes usually have a grain-supported fabric in which quartz represents > 99% of the framework grains. Hand specimens of humicrete are brittle but disintegrate rapidly in 0.1 N-NaOH. Concentration of humate is considered to have occurred by vertically and laterally migrating groundwater, while induration has probably been caused by irreversible drying of the humic substances during periods of seasonal water-table lowering. Radiocarbon dating of an in situ root embedded in indurated humate near Cape Flattery has indicated a ‘background’ age of > 48000 C–14 years.

Type
Articles
Copyright
Copyright © Cambridge University Press 1982

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Alerdice, D. S., Craven, B. R., Creswick, W. & Johnson, D. W. 1978. Humic substances in swamps of the Myall Lakes region, N.S.W Aust. J. soil Res. 16, 4152.CrossRefGoogle Scholar
Andriesse, J. P. 1968/1969. A study of the environment and characteristics of tropical podzols in Sarawak (East Malaysia). Geoderma 2, 201–27.CrossRefGoogle Scholar
Andriesse, J. P. 1969/1970. The development of the podzol morphology in the tropical lowlands of Sarawak (Malaysia). Geoderma 3, 261–79.CrossRefGoogle Scholar
Bird, E. C. F. 1961. The coastal sand barriers of East Gippsland, Australia Geogr. J. 127, 460–68.CrossRefGoogle Scholar
Bleackley, D. & Khan, E. J. A. 1963. Observations on white sand areas of the Berbice Formation, British Guiana J. soil Sci. 14, 4451.CrossRefGoogle Scholar
Brandon, C. E., Buol, S. W., Gamble, E. E. & Pope, R. A. 1977. Spodic horizon brittleness in Leon (Aeric Haplaquod) soils J. soil. Sci. Soc. Am. 41, 951–4.CrossRefGoogle Scholar
Brewer, R. 1964. Fabric and Mineral Analysis of Soils. New York: Wiley.Google Scholar
Clark, B. B. 1967. Sandrock and other features of the cliffs at Mother Ivey's Bay, near Padstow Proc. Ussher Soc. 1 (6), 286.Google Scholar
Coaldrake, J. E. 1955. Fossil soil hardpans and coastal sandrock in southern Queensland Aust. J. sci. 17, 132–3.Google Scholar
Coaldrake, J. E. 1960. Quaternary history of the coastal lowlands of southern Queensland J. geol. Soc. Aust. 7, 403–8.Google Scholar
Coaldrake, J. E. 1961. The ecosystem of the coastal lowlands (Wallum) of southern Queensland. C.S.I.R.O. Aust. Bull. 283.Google Scholar
Coaldrake, J. E. 1962. The coastal dunes of southern Queensland Proc. R. soc. Qd 72, 101–16.Google Scholar
Du Bar, J. R., Johnson, H. S., Thom, B. G. & Hatchell, W. O. 1974. Neogene stratigraphy and morphology, south flank of the Cape Fear arch, North and South Carolina. In Post-Miocene Stratigraphy, Central and Southern Atlantic Coastal Plain (ed. Oaks, R. Q. and Du Bar, J. R.), pp. 139–73. Logan: Utah State Univ. Press.Google Scholar
Flaig, W., Beutelspacher, H. & Reitz, E. 1975. Chemical composition and physical properties of humic substances. In Soil Components, vol. 1, Organic Components (ed. Gieseking, J. E.), pp. 1106. Berlin: Springer Verlag.Google Scholar
Grimes, K. G. 1979. Carbon-14 dates and the evolution of Fraser Island Qd Govt. min J. 80, 7982.Google Scholar
Hardon, H. J. 1936. Podzol profiles in the tropics Natuurk. Tijd. ned Indie 96, 2541.Google Scholar
Hardon, H. J. 1937. Padang soil, an example of podzol in the tropical lowlands Proc. sect. sci. Kon. ned. Akad. Wet. 40, 530–8.Google Scholar
Hardon, H. J. 1938. An example of podzol in tropical lowlands Pedologie 3, 325–31.Google Scholar
Holzhey, C. S., Daniels, R. B. & Gamble, E. E. 1975. Thick Bh horizons in the North Carolina coastal plain. II. Physical and chemical properties and rates of organic addition from surface sources Proc. soil Sci. Soc. Am. 39, 1182–7.CrossRefGoogle Scholar
Hosking, J. S. & Burville, G. H. 1938. A soil survey of part of the Denmark Estate, Western Australia. C.S.I.R.O. Aust. Bull. 115.Google Scholar
Jennings, J. N. 1957. Coastal dune lakes as exemplified from King Island, Tasmania Geogr. J. 123, 5970.CrossRefGoogle Scholar
Jennings, J. N. 1959. The coastal geomorphology of King Island, Bass Strait, in relation to changes in the relative level of land and sea. Rec. Queen Vict. Mus. Launceston, new ser. 11, 39 pp.Google Scholar
Kershaw, A. P. 1978. Record of the last interglacial-glacial cycle from northeastern Queensland Nature, Lond. 272, 159–61.CrossRefGoogle Scholar
Klinge, H. 1965. Podzol soil in the Amazon Basin J. soil Sci. 16, 95103.CrossRefGoogle Scholar
Klinge, H. 1969. Climatic conditions in lowland tropical podzol areas Tropical Ecol. 10, 222–39.Google Scholar
Kodama, H. & Schnitzer, M. 1967. X-ray studies of fulvic acids, a soil humic compound J. Fuel sci. 46, 8794.Google Scholar
Kononova, M. M. 1966. Soil Organic Matter: Its Nature, Its Role in Soil Formation and in Soil Fertility. London: Pergamon.Google Scholar
Kononova, M. M. 1975. Humus of virgin and cultivated soils. In Soil Components, vol. 1, Organic Components (ed. Gieseking, J. E.), pp. 475526. Berlin: Springer Verlag.CrossRefGoogle Scholar
Kurz, H. 1942. Florida coastal dunes and scrub, vegetation and geology. Florida geol. surv. Bull. 23, 154 pp.Google Scholar
Langford-Smith, T. & Thom, B. G. 1969. New South Wales coastal morphology J. geol. Soc. Aust. 16, 572–80.Google Scholar
Marshall, J. F. & Thom, B. G. 1976. The sea level in the last interglacial Nature, Lond. 263, 120–1.CrossRefGoogle Scholar
McGarity, J. W. 1956. Coastal sandrock formations at Evans Head Proc. Linn. soc. N.S.W. 81, 52–8.Google Scholar
Martin, A. E. 1960. Chemical studies of podzolic illuvial horizons. V. Flocculation of humus by ferric and ferrous iron and nickel J. soil Sci. 11, 382–94.CrossRefGoogle Scholar
Misterski, W. & Loginov, W. 1959. A study of some physico-chemical properties of humic acids Soviet soil Sci. 2, 170–81.Google Scholar
Polach, H. A. & Thom, B. G. 1973. Problems of radiocarbon dating logs in coastal sandrock in northern New South Wales, Australia. Abs. 9th INQUA Congr., Christchurch, 293–4.Google Scholar
Prescott, J. A. 1931. The soils of Australia in relation to vegetation and climate. C.S.I.R.O. Aust. Bull. 52, 88 pp.Google Scholar
Prescott, J. A. 1942. A soil map of Australia. C.S.I.R.O. Aust. Bull. 177, 15 pp.Google Scholar
Price, W. A. 1962. Stages in the oxidation colouration in dune and barrier sands with age Bull. geol. Soc. Am. 73, 1281–4.CrossRefGoogle Scholar
Pye, K. 1981. Rate of dune reddening in a humid tropical climate Nature, Lond. 290, 582–4.CrossRefGoogle Scholar
Pye, K. & Switsur, V. R. 1981. Radiocarbon dates from the Cape Bedford-Cape Flattery dunefield, North Queensland Search 12, 225–6.Google Scholar
Richards, P. W. 1941. Lowland tropical podzols and their vegetation Nature, Lond. 148, 129–31.CrossRefGoogle Scholar
Schnitzer, M. & Khan, S. U. 1972. Humic Substances in the Environment. New York: Dekker.Google Scholar
Schnitzer, M. & Khan, S. U. 1978. Soil Organic Matter. Amsterdam: Elsevier.Google Scholar
Stace, H. C. T., Hubble, G. D., Brewer, R., Northcote, K. H., Sleeman, J. R., Mulcahy, M. J. & Hallsworth, E. G. 1968. A Handbook of Australian Soils. Glenside, South Australia: Rellim Tech. Pubs.Google Scholar
Swanson, V. E. & Palacas, J. G. 1965. Humate in coastal sands of northwest Florida. U.S. geol. surv. Bull. 1214 B.Google Scholar
Thom, B. G. 1965. Late Quaternary coastal morphology of the Port Stephens Myall Lakes area, New South Wales J. R. soc. N.S.W. 98, 2336.Google Scholar
Thom, B. G. 1967. Humate in coastal geomorphology Coastal Stud. Bull. 1, 1517.Google Scholar
Thom, B. G. 1978. Coastal sand deposition in southeast Australia during the Holocene. In Landform Evolution in Australasia (ed. Davies, J. L. and Williams, M. A. J.), pp. 197214. Canberra: A.N.U. Press.Google Scholar
Thom, B. G., Bowman, G. M. & Roy, P. S. 1981. Late Quaternary evolution of coastal sand barriers, Port Stephens-Myall Lakes area, central New South Wales, Australia Quat. Res. 15, 345–64.CrossRefGoogle Scholar
Tinsley, J. 1950. The determination of organic carbon by dichromate mixtures Trans. 4th Int. Congr. Soil Sci. 1, 161–4.Google Scholar
Wall, J. R. D. 1964. Topography-soil relationships in lowland Sarawak J. Trop. Geogr. 18, 192–9.Google Scholar
Ward, W. T. 1977(a). Sand movement on Fraser Island: a response to changing climates Occasional Papers in Anthropology, Anthropology Museum, Univ. Qd. 8, 113–26.Google Scholar
Ward, W. T. 1977(b). Quaternary geology and geomorphology of Fraser Island. Geol. Soc. Aust. Qd. Div. Field Conf. Guidebook 1977, 61–4.Google Scholar
Ward, W. T. 1977(c). Geomorphology and soils of the Stratford-Bairnsdale area, East Gippsland, Victoria. C.S.I.R.O. Aust. Soils and Landuse Ser. 57.Google Scholar
Ward, W. T. & Little, I. P. 1975. Times of coastal sand accumulation in southeast Queensland Proc. ecol. Soc. Aust. 9, 313–17.Google Scholar
Ward, W. T., Little, I. P. & Thompson, C. H. 1979. Stratigraphy of two sandrocks at Rainbow Beach, Queensland, and some notes on their composition. Palaeogeogr. Palaeoclimatol. Palaeoecol. 26, 305–16,CrossRefGoogle Scholar
Wright, W. R. & Foss, J. E. 1968. Movement of silt-sized particles in sand columns Proc. soil. Sci. Soc. Am. 32, 446–8.CrossRefGoogle Scholar