Hostname: page-component-78c5997874-mlc7c Total loading time: 0 Render date: 2024-11-14T23:19:33.407Z Has data issue: false hasContentIssue false

The semi-arid environment of Curaçao: a geochemical soil survey

Published online by Cambridge University Press:  01 April 2016

A.J. de Vries*
Affiliation:
Public Works The Hague, Department of Environment, P.O. Box 12651, 2500 DP DEN HAAG, the Netherlands; e-mail: a.j.devries@dsb.denhaag.nl
Rights & Permissions [Opens in a new window]

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

A geochemical soil survey was carried out on the island of Curaçao in October 1992 as part of an overall geochemical characterisation of the three Leeward islands of the Netherlands Antilles. The aim of this soil survey was to provide systematic geochemical data of the rural soils of Curaçao for characterisation, geochemical mapping and environmental application. A total of 122 samples was collected from the topsoils (upper 0.1 m) within a rectangular grid (2 km2). All samples were sieved to a grain size of < 2 mm and analysed for 24 elements by ICP-AES, after decomposition with hot aqua regia. A small, selected set of soil samples was subjected to a more extensive study of soil properties.

It appears from statistical data interpretation of the chemical compositions with techniques like non-linear mapping and cluster analysis that the topsoils of Curaçao can be divided into six homogeneous groups (soil types) with contrasting chemical signatures. Labelled according to their dominant geology, soil process or most striking characteristic, these soil types are defined as follows: sandy limestone soil type, Midden Curaçao soil type, arid/calcareous soil type, basalt West soil type, agriculture-influenced soil type, and the basalt East soil type.

Geochemical contour maps were made that provide a basis for environmental issues on the island. Finally, background levels (baseline data) were derived from the chemical soil composition of several elements, taking into consideration the correlation with the Fe or Al content of these soils. The defined baselines can be used to establish background values for future soil surveys.

Type
Research Article
Copyright
Copyright © Stichting Netherlands Journal of Geosciences 2000

References

Alam, M., 1977. Awa Marga, landbouw en water op Curaçao. Ph.D. thesis Wageningen: 57 pp.Google Scholar
Beckmann, G.G., Thompson, C.H. & Hubble, G.D., 1974. Genesis of red and black soils on basalt on the Darling Downs, Queensland, Australia. Journal of Soil Science 25: 265281.CrossRefGoogle Scholar
Beets, D.J., 1972. Lithology and stratigraphy of the Cretaceous and Danian successions of Curaçao. Ph.D. thesis University of Amsterdam: 153 pp.Google Scholar
Beets, D.J. & MacGillavry, H.J., 1977. Outline of the Cretaceous and Early Tertiary history of Curaçao, Bonaire and Aruba. In: Guide to the field excursions on Curaçao, Bonaire and Aruba. GUA Papers of Geology, Series 1, 10: 16.Google Scholar
Bresler, E., McNeal, B.L. & Carter, D.L., 1982. Saline and sodic soils - principles, dynamics, modeling. Advanced Series in Agricultural Sciences. Springer-Verlag (NewYork): 167227.Google Scholar
Breteler, H.G.M., 1981. Geschiktheid voor akkerbouw, tuinbouw en grasland, de beste gronden van Curaçao, herinterpretatie van de klassen 1 en 2 van de bodemgeschiktheidskaart van het Grommi) & Sogreah rapport (1968). Wageningen: 21 pp.Google Scholar
De Vivo, B., Boni, M., Marcello, A., Di Bonito, M. & Russo, A., 1997. Baseline geochemical mapping of Sardinia (Italy). Journal of Geochemical Exploration 60: 7790.CrossRefGoogle Scholar
Edelman, Th., 1983. Achtergrondgehalten van een aantal anorganische en organische stoffen in de bodem van Nederland, een eerste verkenning. Ministerie VROM (Den Haag): 65 pp.Google Scholar
Grontmij, & Sogreah, , 1968. Water and land resources development plan for the islands of Aruba, Bonaire and Curaçao. Wageningen: 98 pp.Google Scholar
Hamilton, R., 1941. Bijdrage tot de bodemkundige kennis van Nederlands West-Indië, Tropengronden 1: 55 pp.Google Scholar
Hieltjens, A.H.M. & Breeuwsma, A., 1983. Chemische bodemonderzoek-methoden voor bodemkenmerken en anorganische stoffen. Ministerie van VROM (Den Haag): 65 pp.Google Scholar
Klaver, G.Th., 1987. The Curaçao lava formation; an ophiolitic analogue of the anomalous thick layer 2B of the Mid-Cretaceous oceanic plateaus in the Western Pacific and Central Caribbean. GUA Papers of Geology 27: 168 pp.Google Scholar
Loughnan, E.C., 1969. Chemical weathering of the silicate minerals. American Elsevier Publishing Company (NewYork): 145 pp.Google Scholar
Louws, R.J., Vriend, S.P. & Frapponi, G., 1997. De grondwaterkwaliteit van Curaçao. Een hydrogeochemisch onderzoek. H20 30:788791.Google Scholar
Mitchell, J.K., 1993. Fundamentals of soil behaviour. Wiley (New York): 437 pp.Google Scholar
Salminen, R. & Tarvainen, T. 1997. The problem of defining geochemical baselines. A case study of selected elements and geological materials in Finland. Journal of Geochemical Exploration 60:9198.Google Scholar
Sposito, G., 1989. The chemistry of soils. Oxford University Press (NewYork): 281 pp.Google Scholar
Steila, D., 1976. The geography of soils: formation, distribution and management. Prentice-Hall (New Jersey): 22 pp.Google Scholar
Stienstra, P., 1983. Structure and general chemistry of Table Mountain Santa Barbara phosphates, Curaçao, Netherlands Antilles. Geologie & Mijnbouw 62: 275 – 284.Google Scholar
STINAPA, 1977. Guide to the field excursions on Curaçao, Bonaire and Aruba, Netherlands Antilles. GUA Papers of Geology, Serie 1, 10: 120 pp.Google Scholar
Van Breemen, N. & Brinkman, R., 1976. Chemical equilibria and soil formation. In: Bolt, G.H. & Bruggenwert, M.G.M. (eds.): Soil chemistry, A. Basic elements. Elsevier Scientific (Amsterdam): 141170.Google Scholar
Van Sambeek, M.H.G., Eggenkamp, H.G.M. & Vissers, M.J.M., 2000. The groundwater quality of Aruba, Bonaire and Curaçao: a hydrogeochemical study. In: Gaans, P.F.M. & Vriend, S.P. (eds.): Geochemical mapping in the Kingdom of the Netherlands. Geologie en Mijnbouw / Netherlands Journal of Geo-sciences 79 (4): 459466 (this issue).Google Scholar
Vinogradov, A.P., 1959. The geochemistry of rare and dispersed chemical elements in soils. New York Consultance Bureau (New York): 209 pp.Google Scholar
VROM, 1989. Leidraad Bodemsanering. Ministerie van VROM (Den Haag): 90 pp.Google Scholar
Young, A., 1976. Tropical soils and soil survey. Cambridge Geographical Studies 9: 468 pp.Google Scholar