Assessment of spatial variability of cation exchange capacity with kriging and cokriging

Document Type : Research Paper

Authors

1 Soil and Water Research Institute, Agricultural Research, Education and Extension Organization (AREEO), Karaj, Iran

2 Soil Science Dept., Faculty of Agriculture, University of Tehran, Karaj, Iran

3 Researcher of Soil and Water Research Institute, Karaj, Iran

Abstract

Cation exchange capacity (CEC) is one of the most important soil attributes which control some basic properties of soil such as acidity, water and nutrient retaining capacity. However, the measurement of cation exchange capacity in large areas is time consuming and requires high expenses. One way to save time and expenses is to use simple soil covariates and geostatistical methods in mapping CEC. Therefore, the aim of the present research was to investigate the role of soil covariates in the improvement of spatial variability of CEC. The study area is located in southwest Iran on the Aghili plain, Gotvand, Khuzestan province. In this study, ordinary kriging and cokriging methods were used to predict CEC. 107 soil samples were gathered on a random grid of 200-700 m. 74 samples were used for training and 33 samples for testing the results. A principle component analysis was performed for covariate selection. Clay was selected as a covariate in cokriging due to high correlation between clay and CEC[FE1]  in the first principle component analysis. Based on the cross validation result of predicted dataset, RMSE and ME for cokriging were 2.16 and 0.03 cmol (+)/kg respectively, and 3.36 and 0.09 cmol (+)/kg for kriging, respectively. Based on these results, cokriging performed better than kriging for predition of cation exchange capacity since it used a covariate such as clay, for the improvement of CEC spatial prediction. 

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Main Subjects

References

Cahn, M. D., J. W. Hummel, B. H. Brouer, 1994. Spatial
     analysis of soil fertility for site specific crop
     management. Soil Science Society of America
     Journal, 58; 1240-1248.
Cambardella, C. A., T. B. Moorman, J. M. Novak, 1994.
     Field-scale variability of soil properties in centres
     Iowa soils. Soil Science Society of America Journal,
     58; 1501-1511.
Chapman, H. D., 1965. Cation exchange capacity. PP.
     891-901. In: Black, C.A. (Ed.), Methods of Soil
     Analysis, part 2. Second Edition, American Society
     of Agronomy, Madison, WI.
Gee, G. W., J. W. Bauder, 1986. Particle-size Analysis.
     PP. 383 – 411. In A.L. Page (ed.). Methods of soil
     analysis, Part1, Physical and mineralogical methods.
     Second Edition, Agronomy Monograph 9, American
     Society of Agronomy, Madison, WI.
Igwe, C. A., J. T. Nkemakosi, 2007. Nutrient
     element contents and cation exchange capacity
      in fine fractions of south-eastern Nigerian soils
      in relation to their stability. Communications in
     Soil Science and Plant Analysis, 38; 1221-1242.
Horn, A. L., R. A. Düring, S. Gath, 2005. Comparison of the
       prediction efficiency of two pedotransfer functions
    for soil cation exchange capacity. Journal of
    Plant Nutrition and Soil Science, 168; 372-374.
Istok, J. D., J. D. Smyth, A. L. Flint, 1993. Multivariate
      geostatistical analysis of groundwater
     contaminant: a case history. Groundwater, 31;
     63-74.
Jafari, A., P. A. Finke, J. V. De Wauw, S. Ayoubi, H.
     Khademi, 2012. Spatial prediction of USDA –great
     soil groups in the arid Zarand region, Iran: comparing
     logistic regression approaches to predict diagnostic
     horizons and soil types. Eur J Soil Sci., 63; 284–298.
Journal, A. G., C. J.  Huijbregts, 1978. Mining
      Geostatistics. Academic Press, New York, USA. pp.
     1-600.
Jung, W. K., N. R. Kitchen, K. A. Sudduth, S. H.
     Anderson, 2006. Spatial characteristics of clay
     pan soil properties in an agricultural field. Soil
     Science Society of America Journal, 70; 1387-1397.
Khattree, R., D. N. Naik, 2000. Multivariate Data
     Reduction and Discrimination with SAS Software.
     SAS Institute Inc., Cary, NC.
Li, Y., Z. Shi, F. Li, H. Y. Li, 2007. Delineation of site-
     specific management zones using fuzzy clustering
     analysis in a coastal saline land. Computers and
     Electronics in Agriculture, 56; 174-186.
Loeppert, R. H., D. L. Suarez, 1996. Carbonate and
     gypsum, PP: 437-474.In: Sparks, D. L. (ed) Methods
     of soil analysis, part3. Second Edition, American
     Society of Agronomy, Madison, WI.
McBratney, A.B., I.O.A. Odeh, T.F.A. Bishop, M.S.
     Dunbar, T.M. Shatar, 2000. An overview of
     pedometric techniques for use in soil survey.
     Geoderma, 97; 293–327.
Manrique, L.A., C.A. Jones, P.T. Dyke, 1991. Predicting
     cation exchange capacity from soil physicalmand
     chemical properties. Soil Sci Soc Am J. 50; 787–794.
Nelson, D. W., L. Sommers, 1982. Total carbon, organic
     carbon, and organic matter. PP. 539- 579. Methods of
     soil analysis. Part 2. Chemical and microbiological
     properties, Second Edition, American Society of
     Agronomy, Madison, WI.
Obalum, S. E.,  Y. Watanabe, C. A. IgweM. E. Obi,
     2013. Improving on the Prediction of Cation
     Exchange Capacity for Highly Weathered and     Structurally Contrasting Tropical Soils from Their
     Fine-Earth Fractions. In comm. Soil Sci plant Anal.
     pp: 1831-1848.
Rhodes, J.D., 1996. Salinity: electrical conductivity and
     total dissolved solids. PP: 417 – 435. In: Sparks, D.L.
     (Ed.), Methods of Soil Analysis. Part 3, Chemical
     Methods. SSSA Book Series No. 5. ASA, Madison,
     WI.
Shi, W. J., J.Y. Liu, Z. P. Du, Y. J. Song, C. F. Chen,
     T. X. Yue, 2009. Surface modelling of soil pH.
     Geoderma, 150; 113-119.
Shiri, J., A. Keshavarzi, O. Kisi, U. Iturraran-Viveros, A.
     Bagherzadeh, R. Mousavi, S. Karimi, 2017. Modeling  
     soil cation exchange capacity using soil parameters:
     assessing the heuristic models. Comput. Electron.
     Agric., 135; 242-251.
Stein, A., L. C. A. Corsten, 1991. Universal kriging and
     cokriging as regression procedure. Biometrics, 47;
     575-587.
Taghizadeh-Mehrjardi, R., B. Minasny, F. Sarmadian, B.
     P. Malone, 2014. Digital mapping of soil salinity in
     Ardakan region, central Iran. Geoderma. 213;15–28.
Wander, M., G. A. Bollero, 1999. Soil quality
     assessment of tillage impacts in Illinois. Soil
     Science Society of America Journal, 63; 961-971.
White, D., M. Richman, B. Yarnal, 1991. Climate
     regionalization and rotation of principal components.
     International Journal of Climatology, 11; 1-25.
Wu, C. F., J. P. Wu, Y. M. Luo, L. M. Zhang, S. D.
     DeGloria, 2009. Spatial estimation of soil total
     nitrogen using cokriging with predicted soil organic
     matter content. Soil Science Society of America
     Journal, 73; 1676-1681.
Yanai, J., T. Sawamoto, T. Oe, K. Kusa, K. Yamakawa
     K. Sawamoto, T. Naganawa, K. Inubushi, R. Hatano
     T. Kosaki, 2003. Spatial variability of nitrous oxide
     emissions and their soil- related determining factors
      in an agricultural field. Journal of Environmental
     Quality, 32; 1965-1977.
Desert
Volume 24, Issue 1
June 2019
Pages 99-108

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