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Keywords = Vladimir K. Mukhomorov

  • 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
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    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
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    References
    [1]
    Mukhomorov V.K., and Anikina L.M. 2012. Dynamics of Mineral Elements in Plants. Primary Soil Formation. LAP LAMBERT Academic Publishing. Germany. Saarbr?cken. (in Russian).
    [2]
    Mukhomorov V.K., Anikina L.M. Stepanova O.A. (2007) Dinamika produktivnosti i kachestva rastitel'noy produktsii i ikh svyaz's informatsionnym obmenom mezhdu sistemami organicheskoye veshchestvo-mikrobioticheskoye soobshchestvo pri pervichnom pochvoobrazovanii. (The dynamics of efficiency and quality of plant products and their relation with information exchange between systems of organic matter and biotic community during of the primary pedogenesis). In: Modern agrophysics for the high agrotechnologies. International Conference. St. Petersburg, Sept., 25-27, 2007, pp. 210-211. (in Russian).
    [3]
    Mukhomorov V.K., and Anikina L.M. (2008) Information Streams in Coupled Organic Matter-Microbiotic Community Systems of the Root-Inhabited Media under Primary Pedogenic Processes. Russian Agricultural Sciences, 34, 322-324.
    [4]
    Panova G.G., Ermakov E.I., Anikina L.M. Stepanova O.A. (2007) A method of chemical regeneration and sterilization of soil analogues. Inventor?s Certificate of Russian Fed. No. 23021004. Bull. No. 19.
    [5]
    ZheltovYu.I. (1986) Vliyaniye sposobov uvlazhneniya korneobitayemykh sred na produktivnost' rasteniy tomata v reguliruyemykh usloviyakh. (Influence of the ways of moistening of root-inhabited environments on the productivity of tomato plants under controlled conditions). Scientific and technical bulletin of agronomic physics. pp. 73-84. (in Russian).
    [6]
    Ermakov, E.I. (2009). The controllable technogenic agroecosystem of the noosphere level. In: Ermakov E.I. Selected Works. St. Petersburg. pp. 75-80.
    [7]
    Sokolov V.N. (1996) Microworld of argillaceous rocks. Soros Educational Journal. pp. 56-64.
    [8]
    PlatonovO.S., PoloveckaiaV.V. (2012) Features of the chemical compositionand biological activity of sapropel. Tula State Pedagogical University of L. Tolstoy. Bulletin ofnew medical technologies. 1, 105-111.
    [9]
    Udalova O.R. (2014) Thesis. Technological bases of cultivation of tomato plants under controlled agro-ecosystems. St. Petersburg.
    [10]
    Yagodyn BA (1987) Practical work on Agricultural Chemistry. M.
    [11]
    MineevaVG (Ed.). (2001) Workshop on Agricultural Chemistry. MSU.M.
    [12]
    Ermakov E.I., Medvedeva I.V., Mukhomorov V.K. (1997) Influence of natural organic matter in the nutrient solution on the water-mineral metabolism and productivity of tomato plants under controlled conditions. Agrochemistry. 5, 32-40.
    [13]
    GambarovG.M., JuravelN.M., and KorolevY.G. (1990) Statistical modelingand forecasting. Ed. by GrambergA.G.M. Finance and Statistics, (in Russian).
    [14]
    Ermakov, E.I., Medvedev I.V. (1985) Optimizatsiya usloviy zhiznedeyatel'nosti korney pri issledovanii vodno-mineral'nogo obmena i potentsial'noy produktivnosti rasteniy tomata. (Optimization of vital activity conditions of the roots in the study of water and mineral metabolism and potential productivity of tomato plants). In: Physiological objective laws of ontogeny and of plant productivity. pp. 155-185.
    [15]
    Pystyl?nik E.I. (1968) Statisticheskie metody analiza i odrabotki nablydenii (Statistical Methods of Analyzing and Processing Observations). Moscow. Nauka.
    [16]
    Fleiss J.L. (1973) Statistical Methods for Rates and Proportions. New York-Chichester-Brisbane-Toronto-Singapore. John Wiley & Sons.
    [17]
    Handbook of Applicable Mathematics. (1990) Chief Editor: Walter Ledermann. Vol. VI: Statistics. Part B. New York-Chichester-Brisbane-Toronto-Singapore. John Wiley & Sons.
    [18]
    Sir Kendall N. (1981) Time-Series. London and High Wycombe. Charls Griffin and Company Ltd.
  • Open Access Research Article
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    Trends Journal of Sciences Research 2015, 2(2), 64-72. http://doi.org/10.31586/Physics.0202.03
    35 Views 34 Downloads PDF Full-text (696.823 KB)  HTML Full-text
    Abstract
    In the present paper, we propose an explanation of the ambiguity of the results of experiments on the study of high-temperature superconductivity of ammonia systems. At the heart of the theoretical interpretation of the experiments, we put the bipolaron model. In this study, we have shown mathematically that the barrier
    [...] Read more.
    In the present paper, we propose an explanation of the ambiguity of the results of experiments on the study of high-temperature superconductivity of ammonia systems. At the heart of the theoretical interpretation of the experiments, we put the bipolaron model. In this study, we have shown mathematically that the barrier of repulsion between polarons can be effectively reduced if the polarons are in the macroscopic dielectric layers, or capillaries. We constructed the theory of polaron states in the macroscopic dielectric layers. We specify the conditions under which the polarons are hold in the layer between dielectrics. It was found that the electrostatic image forces lead to the appearance of additional forces of attraction between polarons. These forces are conditioned by oscillations of polarons around the position of their fixation. Derivations are given of the upper and lower limits on the width of the gap in which the polaron oscillations are not suppressed. In this case take place disappearance Coulomb repulsion of the polarons. A long-range resonant interaction of two oscillators resulting in the appearance of effective attraction between polarons is discussed. This leads to the formation of diamagnetic singlet bipolarons due to quantum exchange interactions and the effects of electron-electron correlations. For glass capillaries (quasi-one-dimensional bipolaron) and for gap between glass plates (quasi-two-dimensional bipolaron) we give quantitative estimates of the gap width and the critical temperature at which there is a barrier-free formation of the bipolaron in ammonia. Numerical estimates are obtained for a case of the bipolaron in ammonia. We got a quantitative evaluation, which indicate that the barrier-free formation of singlet bipolaron in ammonia begins at temperatures below 80K. As the experiment showed the electrical resistance of ammonia systems decreases abruptly by 10-12 orders of magnitude in this temperature range. At the same time, experiments have shown that for the bulk superconductivity superconducting phase is only ~ 0.01%.  Full article
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    References
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    Kopelevich Ya., da Silva R.R. and Camargo B.C. (2015). Unstable and Elusive Superconductors. Physica C: Superconductivity and its Applications. (in Press).
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    Edwards P.P. (2000). Superconductivity in Metal-Ammonia Solutions. Journal of Superconductivity. 13, no.6, 933-946.
    [9]
    Mukhomorov V. K. (2000). Bipolaron States of Electrons and Magnetic Properties of Metal-Ammonia Systems. Physica Status Solidi (B): Basic Solid State Physics, 219, no. 1, 71-89.
    [10]
    Mukhomorov V. K. (1983). The Energy States and Optical Properties of Bound Two-Electron Quasi-Molecular Self-Localized Impurity Centers in Polar Media. Optics and Spectroscopy, 55, no.2, 145-150.
    [11]
    Mukhomorov V. K. (2011). Bipolarons. Structure. Properties. LAP Lambert Academic Publishing. Saarbr?cken. Germany. (in Russian).
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    Bogolyubov N. N. (1950). On a New Form of the Adiabatic Perturbation Theory in the Problem of Interaction with the Quantum Field. Ukr. Mat. Zh., 2, 3-24, (in Russian).
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    Mukhomorov V. K. (1991). On the Spectrum of Bound States of Self-Trapped Electrons within the Adiabatic and Strong Coupling. Optics. Spectroscopy, 71, 729-734.
    [17]
    Mukhomorov V. K. (1982). Interelectron Correlations in the Two-Electron Selflocalized Formation in Polar Semiconductors. Semiconductors, 16, 700-701.
    [18]
    Mukhomorov V. K. (2013). On the Spatial Symmetry of a Large Bipolaron in View of the Bipolaron Calculations of Kashirina N.I. and Lakhno V.D. Science. Engineering. Technology. (Politechnical Bulletin), no. 4, 11-37 (in Russian).
    [19]
    Mukhomorov V. K. (2014). Landau-Pekar Bipolaron in Singlet and Triplet States. Review of Advances in Physics Theories and Applications, 1, no.2, 9-33.
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    [27]
    Mukhomorov V. K. (2004). Bipolaron Formations and Existence of Periodical Structure in Metal-Ammonia Systems. Physica Scripta., 70, no.5, 330-334.
    [28]
    Cantele G., Ninno D., Iadonisi G., Perroni C.A. and Mukhomorov V. (2006). Thermodynamical and Dynamical Instabilities in the Homogeneous Large-Polaron gas. In: Proceedings of the International School of Physics "Enrico Fermi", Issue: Proceedings of the International School of Physics "Enrico Fermi": Polarons in Bulk Materials and Systems with Reduced Dimensionality, 413-428.
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