Abstract
Goal, Scope and Background
The distribution of elements cannot only scatter widely in investigation areas, but also to a small scale in investigation fields. Chemometric methods are useful tools to describe the spatial distribution of the elements and are suitable to characterize the inhomogeneity in the soil. This knowledge can also be beneficial, among other things, for the creation of problem-adapted sampling strategies. The element distribution at one sampling point, the so-called microinhomogeneity considerably affects the representativeness of pollution assessment for a whole investigation area.
Methods (or Main Features)
The case under investigation was a small area of 1 m2 uncultivated pasture, covered by grass and not specifically polluted. The distribution of 13 elements in the topsoil has been investigated. The samples were taken at the 25 nodes of a regular grid from the upper layer (sampling depth: 10 cm) which covered the tested area. After drying and sieving, the soil was digested by using aqua regia. The elements were determined by different techniques of atomic absorption spectroscopy: flame (Cu, Fe, K, Mn, Na, Zn), graphite furnace (Cd, Cr, Cu, Ni, Pb) and FI-hydride (As, Se). The local gradient method, multivariate statistics and mapping of the element distribution are used for quantitative assessment of the inhomogeneity of the element distribution in course of investigation.
Results and Discussion
The contents of the elements are measured in a small area of 1 m2, and the mean and some important parameters are determined. The contents are highly variable and scatter between the minimum and the maximum, with the standard deviation ranging between 11% and 51%. The observed concentrations were used in formulation of ‘local’ polynomial models which approximated element distributions inside the squares of the grid. Together, the local distribution formed a distribution map for the element over the 1 m2 area which was tested. Also, some global (mean, averaging) characteristics of distribution inhomogeneity were used. These values of global characteristics show no gradient type distribution of the elements over the whole tested area under investigation. Additional information about the inhomogeneity of the investigated area can be obtained by multivariate statistical methods (cluster analysis and principal components analysis) and some selected methods of data presentation (2D and 3D sequential diagrams).
Conclusion
The advantages and disadvantages of the approach are discussed. The mapping and visualization of the element distribution together with the global characteristics of inhomogeneity is a useful and comfortable way of presenting and collecting data of environmental monitoring. The mapping appears to be a most impressive and user-friendly presentation of element distribution. The local inhomogeneity is more ‘intensive’ if more isolines cross a subsquare.
Recommendation and Outlook
The investigation will be continued considering another case study. This particular case study is accentuated by a strong dustlike immisssion and subsequently characterized by a gradient of soil pollution.
Similar content being viewed by others
References
Einax JW, Zwanziger HW, Geiß S (1997): Chemometrics in environmental analysis. VCH, Weinheim
Tauler R (2000): Interpretation of environmental data using chemometrics. In: Barcelo D (ed): Sample handling and trace analysis of pollutants. Elsevier, Amsterdam, pp. 689–736
DIN ISO 11 466 (1997): Bodenbeschaffenheit –Extraktion in Königswasser löslicher Spurenelemente. Beuth, Berlin
Parczewski A (1981): The use of empirical mathematical models in the examination of homogeneity of solids. Anal Chim Acta 130: 221–226
Parczewski A, Danzer K, Singer R (1986): Investigation of the homogeneity of solids with a linear regression model. Anal Chim Acta 191: 461–466
Parczewski A (1991): Microcomputer aided testing, presentation and documentation of inhomogeneity of solids. Polish J Chem 65: 611–619
Parczewski A, Danzer K (1993): Some limitations of global characterization of inhomogeneity of solids. Polish J Chem 67: 961–966
Doerffel K (1990): Statistik in der analytischen Chemie. 5., erw. und überarb. Auflage, Deutscher Verlag für GrundstoffindustrieLeipzig
Einax JW, Kraft J (2002): Small-scale variability of metals in soil and composite sampling. ESPR –Environ Sci & Pollut Res 9 (4): 257–261
StatSoft, Inc. (1999): STATISTICA für Windows [Computer-Programm- Handbuch]. Tulsa, OK: StatSoft, Inc., 2300 East 14th Street, Tulsa, OK 74104, Tel. 001 918 749-1119, Fax: 001 918 749-2217, Email: info@statsoft.com. WEB: http://www.statsoft.com
Author information
Authors and Affiliations
Corresponding authors
Rights and permissions
About this article
Cite this article
Parczewski, A., Kraft, J. & Einax, J.W. Examination and presentation of element distribution in soil. J Soils & Sediments 4, 170–176 (2004). https://doi.org/10.1007/BF02991136
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF02991136