Abstract
Many random processes occur in geochemistry. Accurate predictions of the manner in which elements or chemical species interact with each other are needed to construct models able to treat the presence of random components. Although modelling of frequency distributions with some probabilistic models (for example Gaussian, log-normal, Pareto) has been well discussed in several fields of application, little attention has been devoted to the features of compositional data and, in particular, to their multivariate nature. In this contribution an approach coherent with the properties of compositional information is proposed and used to investigate the shape of the frequency distribution of geochemical indices obtained by robust multivariate analysis. The purpose is to understand data-generation processes from the perspective of compositional theory. The approach is based on use of transformations of the log-ratio family, each with peculiar theoretical and practical advantages, depending on the statistical methods adopted. Accordingly, because, in compositional data, all the relevant information about one term (x i ) of a D-part composition is contained in the ratios to each of the remaining parts x 2,…, x D , analysis of single variables is abandoned. The proposed methodology directs attention to modelling of the frequency distribution of more complex indices, linking all the terms of the composition to better represent the dynamics of geochemical processes. An example of its application is presented and discussed on the basis of consideration of the chemistry of 616 ocean floor basaltic (OFB) glasses from the abyssal volcanic glass data file (AVGDF) of the Smithsonian Institution.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Abramenko, V.I. (2012), Fractal multi-scale nature of solar/stellar magnetic fields, Proceedings of the International Astronomical Union 8(S294), 289–300.
Agterberg, F. (2007), Mixtures of multiplicative cascade models in geochemistry, Nonlinear Process Geophys 14, 201–209.
Ahrens, L. (1954a), The lognormal distribution of the elements-II, Geochim. Cosmochim. Acta 6, 121–131.
Ahrens, L. (1954b), The lognormal distribution of the elements (a fundamental law of geochemistry and its subsidiary),Geochim. Cosmochim. Acta 5, 49–73.
Aitchison, J. (1982), The statistical analysis of compositional data (with discussion), J. R. Stat. Soc. Ser. B-Stat. Methodol. 44(2), 139–177.
Aitchison, J. (1983), Principal component analysis of compositional data, Biometrika 70(1), 57–65.
Aitchison, J. (1986), The Statistical Analysis of Compositional Data. Chapman and Hall, London, 463 pp. Reprint of first edition by The Blackburn Press, 2003.
Aitchison, J. and Brown, J. (1954), On criteria for descriptions of income distribution. Metroeconomica 6, 88–98.
Aitchison, J., Mateu-Figueras, G. and Ng, K. (2003), Characterization of distributional forms for compositional data and associated distributional tests, Math Geol 35(6), 667–680.
Allégre, C. and Lewin, E. (1995), Scaling laws and geochemical distribution, Earth Planet. Sci. Lett. 132, 1–13.
Billheimer, D., Guttorp, P. and Fagan, W. (2001), Statistical interpretation of species composition, J. Am. Stat. Assoc. 96(456), 1205–1214.
Buccianti, A. (2011), Natural laws governing the distribution of the elements in geochemistry: The role of the log-ratio approach, in Pawlowsky-Glahn, V. and Buccianti, A. (Eds.). Compositional Data Analysis: Theory and Applications, Wiley ch 18, 255–266.
Buccianti, A. (2013), Is compositional data analysis a way to see beyond the illusion?, Compt. and Geosc. 50, 165–173.
Buccianti, A. and Magli, R. (2011), Metric concepts and implications in describing compositional changes for world rivers water chemistry, Comput. Geosci. 37(5), 670–676.
Buccianti, A., Mateu-Figueras, G. and Pawlowsky-Glahn, V. (2006), Compositional Data Analysis in the Geosciences. From theory to practice, Geological Society, London, Special Publication 264.
Chayes, F. (1960), On correlation between variables of constant sum, J. Geophys. Res. 65(12), 4185–4193.
Cheng, Q., Agterberg, F.P. and Ballantyne, S.B. (1994), The separation of geochemical anomalies from background by fractal methods, J. Geochem. Explor. 51, 109–130.
Clarke, F. (1889), The relative abundance of the chemical elements, Philosofical Society of Washington Bulletin 11, 131–142.
Clarke, F. (1924), The composition of the earth crust, USGS Professional paper 127,1–117.
Cousens, B.L., Chase, R.L. and Schilling J.G. (2011). Geochemistry and origin of volcanic rocks from Tuzo Wilson and Bowie seamounts, northeast Pacific Ocean, Canadian Journal of Earth Sciences 22(11), 1609–1617.
Daszykowski, M., Kaczmarek, K., Vander Heyden, Y., Walczak, B. (2007), Robust statistics in data analysis—A review. Basic Concepts, Chemom. and Intell. Lab. System. 85, 203–219.
Egozcue, J.J. and Pawlowsky-Glahn, V. (2005), Groups of parts and their balances in compositional data analysis, Mathem Geol 37(7),795–828.
Egozcue, J.J. and Pawlowsky-Glahn, V. (2006), Simplicial geometry for compositional data, in: Buccianti, A., Mateu-Figueras G. and Pawlowsky-Glahn V. (Eds.). Compositional Data Analysis in the Geosciences: from theory to practice Special Publication 264, Geological Society, London, 12–28.
Egozcue, J.J., Pawlowsky-Glahn, V., Mateu-Figueras, G. and Barcelo-Vidal, C. (2003), Isometric logratio transformations for compositional data analysis, Math Geol 35(3), 279–300.
Everitt B. and Hothorn T. (2011), An introduction to Applied Multivariate Analysis with R, Springer, Berlin.
Federer, J. (1988), Fractals Plenum, New York, p. 283.
Filzmoser, P., Hron, K. and Reimann, C. (2009a), Univariate statistical analysis of environmental (compositional) data: problems and possibilities, Sci. Total Environ. 407, 6100–6108.
Filzmoser, P., Hron, K. and Reimann, C. (2009b), Principal component analysis for compositional data with outliers, Environmetrics 20(6), 621–632.
Filzmoser, P. and Todorov, V. (2013), Robust tools for the imperfect world, Information Sciences 245(1), 4–20.
Frisch, U. (1995), Turbulence, The Legacy of A.N. Kolmogorov, Cambridge University Press.
Goldschmidt, V.M. (1933), Grundlagen der quantitativen geochimie, Fortschrift Mineralogie 17(2), 112–156.
Goncalves, M.A. (2001), Characteriszation of geochemical distributions using multifractals models, Math. Geosc. 33, 41–61.
Hofmann, A. (2003), Sampling mantle eterogeneity through oceanic basalts: Isotopes, vol 2. in Treatise on Geochemistry, The mantle and Core, Carlson R.W. (Ed.), Elsevier, Amsterdam.
Hubert, M., Rousseeuw P.J., and Vanden Branden K. (2005), ROBPCA: A new approach to robust Principal Component Analysis, Technometrics 47(1), 64–79.
Jenner F., O'Neill H. (2012), Analysis of 60 elements in 616 ocean floor basaltic glasses, Geochem. Geophys. Geosyst. 13(1), 1–11.
Kapteyn, J. (1903), Skew frequency distributions in biology and statistics, Astronomical Laboratory, Groningen, Noordhoff.
Kondepudi, D. and Prigogine, I. (1999), Modern thermodynamics, Wiley, Chichester, p. 486.
Le Maitre, R.W. (1968), Chemical variation within and between volcanic rocks series—a statistical approach, J. Petrol. 9, 220–252.
Li, C., Ma, T. and Shi, J. (2003), Application of a fractal method relating concentrations and distances for separation of geochemical anomalies from background, J. Geochem. Explor 77, 167–175.
Liebovitch, L. and Scheurle, D. (2000), Two lessons from fractals and chaos, Complexity 5(4), 34–43.
Ma, T., Li, C. and Lu, Z. (2014), Estimating the average concentration of minor and trace elements in surficial sediments using fractal methods, J. Geochem. Explor. 139, 207–216.
Mateu-Figueras, G. and Pawlowsky-Glahn, V. (2008), A critical approach to probability laws in geochemistry, Math Geosci. 40, 489–502.
Mateu-Figueras, G., Pawlowsky-Glahn, V. and Barcelo-Vidal, C. (2005), The additive logistic skew-normal distribution on the simplex, Stoch. Environ. Res. Risk Assess. 19(3), 205–214.
Mateu-Figueras, G., Pawlowsky-Glahn, V. and Egozcue, J.J. (2013), The normal distribution in some constrained sample spaces, SORT 37, 29–56.
Melson, W., O’Hearn, T. and Jarosewich, E. (2002), A data brief on the Smithsonian abyssal volcanic glass data file, Geochem. Geophys. Geosyst. 3(4), 2001GC000249.
Mitzenmacher, M. (2004), A brief history of generative models fro power law and lognormal distributions, Internet Mathematics 1(2), 226–251.
Ott, W. (1990) A physical explanation of the lognormality of pollutant concentrations, Journal of Air and Waste Management Association 40(10), 1378–1383.
Pawlowsky-Glahn, V. and Buccianti, A. (2011), Compositional Data Analysis. Theory and Applications, Wiley, London.
Pawlowsky-Glahn, V. and Egozcue, J. (2001), Geometric approach to statistical analysis on the simplex, Stoch. Environ. Res. Risk Assess. 15(5), 384–398.
Pearson, K. (1897), Mathematical contributions to the theory of evolution. On a form of spurious correlations which may arise when indices are used in the measurements of organs, Proc. R. Soc. London 60, 489–498.
R Development Core Team (2007). R: A Language and Environment for Statistical Computing. R Foundation for Statistical Computing, Vienna, ISBN 3-900051-07-0.
Reimann, C. and Filzmoser, P. (1999), Normal and lognormal data distribution in geochemistry: death of a myth. Consequences for the statistical treatment of geochemical and environmental data, Environ. Geol. 39(9), 1001–1014.
Rollinson, H.R. (1993), Using geochemical data: evaluation, presentation, interpretation, Pearson Prentice Hall, England.
Rollinson, H.R. (1992), Another look at the constant sum problem in geochemistry, Mineral. Magaz. 56(385), 469–475.
Rousseeuw, P.J. (1984), Least Median of Squares Regression, Journal of the American Statistical Association 79, 871–880.
Templ, M., Hron, K. and Filzmoser, P. (2011), robCompositions: An R-package for robust statistical analysis of compositional data, in: Compositional Data Analysis: Theory and Applications (Pawlowsky-Glahn and Buccianti eds.), Wiley, 341–355.
Todorov, V. and Filzmoser, P. (2010), Robut statistics for one-way MANOVA, Computational Statistics and Data Analysis 54, 37–48.
Van den Boogaart, K.G. and Tolosana-Delgado R. (2013), Analyzing Compositional Data with R, Springer, Berlin.
Verboven S. and Hubert M. (2005), LIBRA: a MATLAB library for robust analysis, Chemom. and Intell. Labor. System. 75, 127–136.
Wedepohl, H. (1955), The composition of the Earth crust, Geochim. Cosmochim. Acta 59, 1217–1239.
Wehrens, R. (2011), Chemometrics with R. Multivariate Analysis in the Natural Sciences and Life Sciences, Springer, Berlin.
Xie, X. and Yin, B. (1993), Geochemical patterns from local to global, J. Geochem. Explor. 47, 109–129.
Acknowledgments
This work has received financial support from the University of Florence (I) through the project ex 60 %—2012 and Tuscany Region (I) and Lamma Consortium through the Geobasi project. Referees are kindly thanked for their valuable revision of the first version of this work.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Buccianti, A. Frequency Distributions of Geochemical Data, Scaling Laws, and Properties of Compositions. Pure Appl. Geophys. 172, 1851–1863 (2015). https://doi.org/10.1007/s00024-014-0963-z
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00024-014-0963-z