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Keywords = Mineral Substrates

  • Open Access Research Article
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    Trends Journal of Sciences Research 2014, 1(1), 1-11. http://doi.org/10.31586/Agrochemistry.0101.01
    93 Views 256 Downloads 3 Citations PDF Full-text (461.204 KB)  HTML Full-text
    Abstract
    We present the results of a comprehensive long-term experiment on intensive cultivation of wheat and tomato plants to initially abiogenous mineral substrate. The experiment simulates the primary processes of soil formation. For the first time is established dynamic synergistic and antagonistic interrelations between the chemical elements (Si, Al, Fe, Mg,
    [...] Read more.
    We present the results of a comprehensive long-term experiment on intensive cultivation of wheat and tomato plants to initially abiogenous mineral substrate. The experiment simulates the primary processes of soil formation. For the first time is established dynamic synergistic and antagonistic interrelations between the chemical elements (Si, Al, Fe, Mg, Ca, K, P, S, Cl, Na, Mn, Zn) in various plant tissues (roots, fruits, grain, stems, leaves) under condition of primary soil formation. We have identified the dynamics of accumulation and differentiation of collective state of the chemical elements in different plant tissues by the methods of information theory.  Full article
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    References
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    [12]
    Mukhomorov V.K. and Anikina L.M. (2011). Dynamics of chemical elements in plants. Primary soil formation. Lambert Academic Publisher. Saarbr?cken. Germany. 2012 (in Russian). 265 p.
    [13]
    Ermakov E.I. and Mukhomorov V.K. (2001). Evolution of diversity measures as a reflection of the process of primary soil formation in a model soil-plant system. Doklady Biochemistry and Biophysics. 379, 297-301.
    [14]
    Ermakov E.I. and Anikina L.M. (2007). Formation of organic compounds and their role in the transformation of mineral rooting medium in a controlled agroecosystem. Russian Agricultural Sciences. ? 6, 30-32.
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    Samsonova N.E. (2005). Kremniy v pochve i rasteniyakh. (Silicon in soil and plants). AgroKhimia. (Agrochemistry). ?6, 76-86.
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    Ermakov E.I., Mukhomorov V.K. and Anikina L.M. (2006). Cause-and-effect relations in the distribution of chemical elements in plant organs during long-term cultivation in a regulated agroecosystem. Russian Agricultural Sciences. no. 3, 1-4.
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    Mukhomorov V.K. (2013). Dynamics of the information exchange and the causal-and-effect relationships in plants under controlled conditions. World Journal of Agricultural Research. 1, no.1, 18-24.
    [19]
    Mukhomorov V.K. and Anikina L.M. (2011). Information flows between organic matter of the roots environment and elemental chemical composition of plants under primary pedogenic conditions. Russian Agricultural Sciences. 37, no. 4, 322-326.
    [20]
    Ermakov E.I. and Mukhomorov V.K. (2009). Productional process of plants and the diversity of interactions of edaphic factors in a controlled agroecosystem. In: Ermakov E.I. Selected works. Eds. Yakushev V.P., Panova G.G., Stepanova O.A. St.-Petersburg, pp.48-54.
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    Mukhomorov V.K. and Anikina L.M. (2009). Information streams and plant productivity. American-Eurasian Journal of Agricultural & Environmental Sciences. 5, 387-392.
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    Ermakov E.I. and Medvedeva I.V. (1985). In: Physiological patterns of ontogeny and plant productivity. Leningrad. pp. 155- 185.
  • Open Access Research Article
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    Trends Journal of Sciences Research 2014, 1(1), 17-25. http://doi.org/10.31586/Agrophysical.0101.03
    54 Views 205 Downloads 1 Citations PDF Full-text (221.837 KB)  HTML Full-text
    Abstract
    We result statistical analysis of experimental data on physical modeling of primary soil formation under long and continuous cultivation of plants on initially abiogenous mineral substrates (granite crushed stone, zeolite). The purpose of the experiment was to follow the dynamics of the evolutionary changes in the mineral substrate under condition
    [...] Read more.
    We result statistical analysis of experimental data on physical modeling of primary soil formation under long and continuous cultivation of plants on initially abiogenous mineral substrates (granite crushed stone, zeolite). The purpose of the experiment was to follow the dynamics of the evolutionary changes in the mineral substrate under condition long-term operation. We used the information approach to quantitative analyze of the relationship of primary soil formation process with the vital activity of plants (tomato, spring wheat) under controlled conditions. We analyzed the dynamics of the diversity of emerging organic matter in the mineral substrate and the biotic community. To quantify the diversity of multicomponent systems, we used information function. We have shown that the dynamics of plant productivity was statistically significant related to the parameter of information exchange between emerging organic matter and biotic community. It has been established that the increase in the total content of organic matter in the mineral substrate does not have a statistically significant correlation with the productivity of plants.  Full article
    Figures

    Figure 6 of 7

    References
    [1]
    Mukhomorov V.K., and Anikina L.M. (2012) Dynamics of Mineral Elements in Plants. Primary Soil Formation. LAMBERT Academic Publishing. Saarbr?cken (in Russian).
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    Assing I.A. (1950) Izv. Akad. Nauk Kazakh. SSR. Ser. Pochv., no.6, 101-108.
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    Ermakov E.I. (1984) USSR Author?s Certificate, Bull. 21.
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    Ermakov A.I. (1987) Methods of Biochemical Investigation of Plants. Leningrad (in Russian).
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    [9]
    Kolmogorov A.N. (1987) Information Theory and Theory of Algorithms. Nauka, Moscow (in Russian).
    [10]
    Mukhomorov V.K., and Anikina L.M. (2011) Information Flows between Organic Matter of the Roots Environment and Elemental Chemical Composition of Plants under Primary Pedogenic Conditions. Russian Agricultural Sciences, 37, 322-326.
    [11]
    Essays on the Use of Information Theory in Biology. (1953) Kastler H., Ed. Univ. Illinois Press, Urbana.
    [12]
    Mukhomorov V.K., and Anikina L.M. (2014). Evolutionary Dynamics of Intercoupling of the Chemical Elements in Plants and Primary Soil-Forming Processes. Trends Journal of Sciences Research, 1(1), 1-11.
    [13]
    Fleis J. (1973) Statistical Methods for Rates and Proportions. Wiley, New York.
    [14]
    Ermakov E.I., Anikina L.M. and Mukhomorov V.K. (1990). Soderzhaniye nitratov v produktsii ovoshchnykh i zernovykh kul'tur v zavisimosti ot kolichestva organicheskogo veshchestva v korneobitayemykh sredakh (The nitrate content in the production of vegetable and cereal crops, depending on the amount of organic matter in the rooting medium). Doklady Rossiyskoy akademii sel'skokhozyaystvennykh nauk (Reports of the Russian Academy of Agricultural Sciences), no.11,14-17. (in Russian).
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