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Optimization Model for the Russian Electric Power Generation Structure to Reduce Energy Intensity of the Economy

Author

Listed:
  • Alexander N. Semin

    (Ural State Mining University, Russia,)

  • Vadim V. Ponkratov

    (Financial University Under the Government of the Russian Federation, Russia,)

  • Kirill G. Levchenko

    (Financial University Under the Government of the Russian Federation, Russia,)

  • Andrey S. Pozdnyaev

    (Bauman Moscow State Technical University, Russia,)

  • Nikolay V. Kuznetsov

    (State University of Management, Russia,)

  • Olga V. Lenkova

    (Tyumen Industrial University, Russia.)

Abstract

In the context of high energy intensity of the country s economy, contributing to a decrease in the industry competitiveness of the Russian Federation, it is relevant to develop scientific approaches to energy efficiency provision. The article is aimed at stimulating the optimal structure of electric power generation in Russia, promoting energy conservation and lowering energy intensity of the economy. The Cobb-Douglas production function was used to determine the dependence of the gross electric output on such production factors as labor costs and capital. Based on the expert evaluation method, the sources of electricity generation were differentiated according to the level of labor intensity. An optimization model has been developed for electric power generation structure in Russia in the context of actual energy generation sources: nuclear power plants; natural gas fired thermal power plants , coal and fuel oil fired power plants; hydropower plants; solar power plants; wind power plants; tidal power plants; and biofuel power plants. The percentage changes in the consumption of energy resources and power generation, ensuring a decrease in the energy intensity of the Russian Gross Domestic Product by 19.1%, are argued. The system of optimization measures has been substantiated; their practical implementation will contribute to the steady decline in energy intensity of the Russian economy, effective energy consumption and the growth of the country s energy potential, with regard to ensuring structural changes in the energy sector.

Suggested Citation

  • Alexander N. Semin & Vadim V. Ponkratov & Kirill G. Levchenko & Andrey S. Pozdnyaev & Nikolay V. Kuznetsov & Olga V. Lenkova, 2019. "Optimization Model for the Russian Electric Power Generation Structure to Reduce Energy Intensity of the Economy," International Journal of Energy Economics and Policy, Econjournals, vol. 9(3), pages 379-387.
    • Handle: RePEc:eco:journ2:2019-03-43
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    References listed on IDEAS

    as
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    Cited by:

    1. Chen Pei Zhao & Gurgen Gukasyan & Valery Bezpalov & Valeriy Prasolov, 2020. "Development of Modern Standards for Energy Efficiency of Industrial Enterprises within the European Union Policy," International Journal of Energy Economics and Policy, Econjournals, vol. 10(6), pages 451-459.
    2. Svetlana Balashova & Svetlana Ratner & Konstantin Gomonov & Andrey Berezin, 2020. "Modeling Consumer and Industry Reaction to Renewable Support Schemes: Empirical Evidence from the USA and Applications for Russia," International Journal of Energy Economics and Policy, Econjournals, vol. 10(3), pages 158-167.
    3. Sergey Kashurnikov & Valeriy Prasolov & Vladimir Gorbanyov & Rodion Rogulin, 2020. "Nuclear Power Production: The Future or the Past?," International Journal of Energy Economics and Policy, Econjournals, vol. 10(5), pages 131-141.
    4. Nurlan Kurmanov & Ulukbek Aliyev & Aizhan Satbayeva & Gulmira Kabdullina & Darkhan Baxultanov, 2020. "Energy Intensity of Kazakhstan s GDP: Factors for its Decrease in a Resource-export Developing Economy," International Journal of Energy Economics and Policy, Econjournals, vol. 10(5), pages 447-453.

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    More about this item

    Keywords

    Energy Intensity of the Russian Economy; Energy Resources; Optimization Model for Electric Power Generation Structure; Power Industry; Economic Energy Efficiency;
    All these keywords.

    JEL classification:

    • Q4 - Agricultural and Natural Resource Economics; Environmental and Ecological Economics - - Energy
    • L16 - Industrial Organization - - Market Structure, Firm Strategy, and Market Performance - - - Industrial Organization and Macroeconomics; Macroeconomic Industrial Structure
    • L52 - Industrial Organization - - Regulation and Industrial Policy - - - Industrial Policy; Sectoral Planning Methods

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