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Keywords = Chemical Elements

  • 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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    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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  • Open Access Research Article
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    Trends Journal of Sciences Research 2014, 1(1), 28-37. http://doi.org/10.31586/Agrophysical.0101.05
    309 Views 623 Downloads 1 Citations PDF Full-text (1.969 MB)  HTML Full-text
    Abstract
    We analyze the experimental data on the dynamics of water and mineral metabolism of tomato plants by using the methods of spectral analysis. Plants were cultivated under controlled conditions. We have used the various compositions of juvenile analogues of thin-layer soil. It is shown that the composition of the soil
    [...] Read more.
    We analyze the experimental data on the dynamics of water and mineral metabolism of tomato plants by using the methods of spectral analysis. Plants were cultivated under controlled conditions. We have used the various compositions of juvenile analogues of thin-layer soil. It is shown that the composition of the soil analogue significantly affects the dynamics of water-mineral metabolism of plants and plant productivity. It was found that the dynamics of the water and mineral metabolism of plants has a clear oscillatory structure. We have identified the most intense frequencies of this process. It was found that in order to maximize the productivity of plants it is necessary that the process of transpiration should contain simultaneously both high-frequency and low-frequency periodicities. This creates the most favorable environment for the development and functioning of the plant root system. It was shown that vibrations of water metabolism closely connected with the vibrations of the content of chemical elements in plants.  Full article
    Figures

    Figure 1 of 9

    References
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