theoretical bases of perspective chemical sources of current (CSC) and ultra-high-volume capacitor structures (UCS) for electric energy accumulators
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2018-04-15 https://doi.org/10.14419/ijet.v7i2.13.12672 -
Thin Film Technology, Chemical Power Source, Ultra-High-Volume Capacitor Structures, Electric Energy Accumulators, Energy Consumption, Electrode Materials, Battery, Mechanism of Electric Energy Accumulation, Electrolyte. -
Abstract
The paper analyzes thin-film technologies for advanced CSC and UCS. It is shown that the amount of accumulated energy is determined by the work of moving the charges in a given direction. This dependence determines the energy intensity of the CSC and UCS shows that the process of accumulation of electric energy in them is the same, and is determined mainly by polarization effects in the system. Because the mechanism of accumulation of electric energy in the CSC and UCS from a physical point of view is the same, there is a possibility to combine design solutions and to create a unified electrode material for a CSC and UCS in thin-film technology. In this case, it is possible to increase the specific energy capacity of the energy storage device while increasing its specific power in a single design solution. The traditional design of CSC and electrolytic UCS focused on the formation of electrode materials for thick-film technology. From this point of view, thin-film technologies, which have been actively developed recently, are promising. The prospect of developing thin-film technologies is associated with the use of nanomaterials and nanostructures, which can form more energy-intensive materials and significantly change the processes of converting the energy of the double electric layer and chemical interaction into electrical energy. The task of the article is to study thin-film technologies theoretically and experimentally in order to determine their development prospects for high-energy current sources, determine the ranges of their use and the possibility of industrial implementation. However, recently there has been a tendency to reduce the dynamics of growth in energy intensity of CSC generated by this technology.
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References
[1] Blomgren, G. E. The Development and Future of Lithium Ion Batteries / G. E. Blomgren // Journal of the Electrochemical Society. – 2017. – Vol. 164, Issue 1. – P. A5019-A5025. – DOI: 10.1149/2.0251701jes – http://jes.ecsdl.org/content/164/1/A5019.full
[2] Myung, S. T. Nickel-Rich Layered Cathode Materials for Automotive Lithium-Ion Batteries: Achievements and Perspectives / S.-T. Myung, F. Maglia, K.-J. Park, C. S. Yoon, P. Lamp, S.-J. Kim, Y.-K. Sun // ACS Energy Letters. – 2017. – Vol. 2. – P. 196-223. – DOI: 10.1021/acsenergylett.6b00594. – http://pubs.acs.org/doi/pdfplus/10.1021/acsenergylett.6b00594
[3] Christiansen, C. Energy Storage Study: A Storage Market Review and Recommendations for Funding and Knowledge Sharing Priorities / C. Christiansen, B. Murray, G. Conway // AECOM Australia for Australian Renewable Energy Agency. – 13 July 2015. – P. 32. – (http://arena.gov.au/files/2015/07/AECOM-Energy-Storage-Study.pdf).
[4] Kitsyuk E. P. “Research and development of processes for the formation of nanostructured electrodes of electrochemical energy storage devicesâ€, thesis for the degree of Candidate of Engineering Sciences (Ph.D.) 05.27.06 – technology and equipment for the production of semiconductors, materials and devices of electronic equipment MIET, Moscow, 2017
[5] Lebedev E. F. “Development of formation processes and study of properties of elements of heat release and energy storage for thermoelectric batteriesâ€, thesis for the degree of Candidate of Engineering Sciences (Ph.D.), specialty 05.27.06. MIET, Moscow, 2017
[6] VU DYC KHOAN “STUDY AND DEVELOPMENT OF MULTILAYER THIN-FILM ELECTROLYTIC CELLSâ€, dissertation on competition of a scientific degree of Candidate of Engineering Sciences (Ph.D.), specialty 05.27.06 Moscow – 2017.
[7] Melvin-Hughes E.A. “Physical chemistry†Publishing house I.L. Moscow 1962
[8] Gerasimov Ya.I.; Dreving V.P.; Eremin E.N., etc. the general editorship of A.A. Gerasimov. “Course of physical chemistryâ€, Chemisty Publishing house, Moscow 1969
[9] Prigozhin M. and Defay R. “Chemical thermodynamicsâ€. Publishing house “Binomâ€, Moscow 2010.
[10] Fikhtengolts G.M. “Course of differential and integral calculationâ€. Publishing house “Physico-mathematical literature†Moscow 1969
[11] Suzdalev I.P. “Nanotechnology: Physical chemistry of nanoclusters, nanostructures and nanomaterials†Ed. Moscow: Book house “Librokomâ€, 2009.
[12] Sleptsov V.V. “Physico-chemical fundamentals of nanomaterials and nanotechnologyâ€. OOO “Sam poligrafist†Moscow 2015.
[13] R. R. Salem “Physical chemistry. The beginning of theoretical electrochemistry†Publisher: “Komkniga†2010.
[14] B. B. Damaskin, O. A. Petriy, G. A. Tsirlina. “Electrochemistry†publishing house “Chemistry†2010
[15] Lewis George, Randall.M “Chemical thermodynamicsâ€. Publishing house “ONTI Khimteoret†Moscow 1936
[16] Salem P. P. “The theory of the double layerâ€. Publishing house Fizmatlit, Moscow, 2003
[17] Matveev A.N. “Electricity and magnetismâ€. Publisher Lan Saint Petersburg-Moscow 2010
[18] Belyaev B.A., Drokin N. A. Impedance spectra of thin permalloy films with nanostructure, solid state Physics, 2012, vol.54, iss.2, pp. 340-346.
[19] B.I.Sedunov, D. A. Frank-Kamenetsky,â€Dielectric permittivity of biological objectsâ€, Physical Sciences Success, April 1963, v. LXXIX, iss. Four p. 617-639.
[20] The reference book “Physical quantities†Publishing house Energoatomizdat, Moscow, 1991
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How to Cite
Vladimir Vladimirovich, S., Dmitry Yuryevich, K., & Anna Olegovna, D. (2018). theoretical bases of perspective chemical sources of current (CSC) and ultra-high-volume capacitor structures (UCS) for electric energy accumulators. International Journal of Engineering & Technology, 7(2.13), 247-251. https://doi.org/10.14419/ijet.v7i2.13.12672Received date: 2018-05-10
Accepted date: 2018-05-10
Published date: 2018-04-15