Труды сотрудников ИВМ СО РАН

[Text] / M. M. Simunin [et al.] // Tech. Phys. Lett. - 2015. - Vol. 41, Is. 11. - P1047-1050, DOI 10.1134/S1063785015110103. - Cited References:20. - This work was supported financially by the Russian Science Foundation, project no. 15-19-10017. . - ISSN 1063-7850. - ISSN 1090-6533РУБ Physics, Applied

Аннотация: A structure based on porous anodic alumina with through pores is synthesized. This structure may be of some interest in terms of fabricating electrically switchable membranes. Conducting tubulenes connected to a common input electrode are located in the pores of the structure. It is hypothesized that enhancement of the electric field nonuniformity associated with the indicated structure morphology should help raise the degree of ionic selectivity of the membrane and broaden the range of permissible concentrations of ions in the processed solution. An suggestion regarding the structure of synthesized tubulenes in the context of the problem of suppressing the physical sorption of ions on the pore surface and raising the hydrogen and oxygen reduction potentials relative to those of state-of-the-art field-switchable membranes is also made.

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Держатели документа:
Natl Res Univ Elect Technol MIET, Moscow 124498, Russia.
Siberian Fed Univ, Krasnoyarsk 660041, Russia.
Russian Acad Sci, Siberian Branch, Krasnoyarsk Sci Ctr, Krasnoyarsk 660036, Russia.
Russian Acad Sci, LV Kirensky Phys Inst, Siberian Branch, Krasnoyarsk 660036, Russia.
Russian Acad Sci, Inst Computat Modeling, Siberian Branch, Krasnoyarsk 660036, Russia.

Доп.точки доступа:
Simunin, M. M.; Khartov, S. V.; Shiverskii, A. V.; Zyryanov, V. Ya.; Fadeev, Y. V.; Фадеев Ю.В.; Voronin, A. S.; Russian Science Foundation [15-19-10017]

/ D. V. Lebedev [et al.] // Pet. Chem. - 2017. - Vol. 57, Is. 4. - P306-317, DOI 10.1134/S096554411704003X. - Cited References:52. - This work was supported by the Russian Science Foundation, grant no. 15-19-10017. Instrumental analysis of the materials was performed in the Shared Equipment Center at the Krasnoyarsk Scientific Center, Siberian Branch of the Russian Academy Sciences. . - ISSN 0965-5441. - ISSN 1555-6239РУБ Chemistry, Organic + Chemistry, Physical + Energy & Fuels + Engineering,

Аннотация: A novel type of ion-selective membranes based on Nafen(TM) alumina nanofibers coated with carbon is proposed. The membranes are produced by filtration of a Nafen nanofiber suspension through a porous support followed by drying and sintering. A thin carbon layer (up to 2 nm) is deposited on the nanofibers by chemical vapor deposition (CVD). Its formation is confirmed by the results of Raman spectroscopy and visually observed in TEM images. According to low temperature nitrogen adsorption experiments, the formation of carbon layer leads to decreasing pore size (the maximum of pore size distribution shifts from 28 to 16 nm) and the corresponding decrease of porosity (from 75 to 62%) and specific surface area (from 146 to 107 m(2)g(-1)). The measurement of membrane potential in an electrochemical cell has shown that the deposition of carbon on the membrane results in high ionic selectivity. In an aqueous KCl solution, the membranes display high anion selectivity with anion and cation transference numbers of 0.94 and 0.06, respectively. The fixed-charge density of membrane has been determined by fitting the experimental data using the Teorell-Meyer-Sievers model. It has been found that the membrane fixed-charge density increases with increasing electrolyte concentration. Possible applications of the membranes produced include nanofiltration, ultrafiltration, and separation of charged species in mixtures. The formation of a conductive carbon layer on the pore surface can be employed for fabricating membranes with switchable ion-transport selectivity.

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Держатели документа:
Russian Acad Sci, Inst Computat Modeling, Siberian Branch, Krasnoyarsk, Russia.
Russian Acad Sci, Siberian Branch, Mol Elect Dept, Krasnoyarsk Sci Ctr, Krasnoyarsk, Russia.
Natl Res Univ Elect Technology MIET, Moscow, Russia.
Russian Acad Sci, Siberian Branch, Inst Chem & Chem Technol, Krasnoyarsk, Russia.

Доп.точки доступа:
Lebedev, D.V.; Лебедев Д.В.; Shiverskiy, A. V.; Simunin, M. M.; Solodovnichenko, V.S.; Солодовниченко В.С.; Parfenov, V. A.; Bykanova, V. V.; Khartov, S. V.; Ryzhkov, I.I.; Рыжков, Илья Игоревич; Russian Science Foundation [15-19-10017]

/ L. Kamenshchikov, I. Krasnov // CEUR Workshop Proceedings : CEUR-WS, 2017. - Vol. 1839: 2016 International Conference Mathematical and Information Technologies, MIT 2016 (28 August 2016 through 5 September 2016, ) Conference code: 127940. - P324-333 . -
Аннотация: Simulations of the resonant ions stochastic dynamics in the polychromatic optical field are presented. We prove the possibility of long-Term four-And nine-particle ionic Coulomb planar clusters (crystals) by all-optical method. An estimate of lifetime of a single particle in an optical lattice is also carried out. Our analysis is based on the numerical solution of the stochastic differential equations with multiplicative noise using MVS-100K and MVS-10P supercomputers.

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Держатели документа:
Institute of Computational Modeling of SB RAS, Krasnoyarsk, Russian Federation

Доп.точки доступа:
Kamenshchikov, L.; Krasnov, I.

[Текст] : статья / Д. В. Лебедев [и др.] // Мембраны и мембранные технологии. - 2017. - Т. 7, № 2. - С. 86-98, DOI 10.1134/S2218117217020031 . - ISSN 2218-1172
Аннотация: Предложен новый тип керамических мембран с ионной селективностью на основе нановолокон оксида алюминия (NafenTM), покрытых слоем углерода. Синтез мембран осуществляется методом вакуумной фильтрации коллоидного раствора волокон Nafen с последующим термическим отжигом и нанесением углеродного слоя методом химического осаждения из газовой фазы (chemical vapor deposition, CVD). Данные просвечивающей электронной микроскопии и спектроскопии комбинационного рассеяния подтверждают формирование углеродного слоя толщиной до 2 нм на нановолокнах. По данным низкотемпературной адсорбции азота, это приводит к уменьшению размера пор (максимум функции распределения смещается от 28 к 16 нм) и соответственному снижению пористости (с 75 до 62%) и удельной поверхности мембраны (с 146 до 107 м2 г–1). С помощью потенциометрического метода установлено, что нанесение углеродного слоя на мембраны из волокон Nafen придает им выраженные ионоселективные свойства. Измерения в водном растворе KCl показали, что полученные мембраны являются анион-селективными с числами переноса 0.94 для аниона и 0.06 для катиона. Определена плотность фиксированного заряда мембран путем аппроксимации экспериментальных данных моделью Теорелла–Мейера–Сиверса. Показано, что плотность заряда возрастает с увеличением концентрации электролита. Полученные мембраны могут быть применены в области нано- и ультрафильтрации, а также для разделения заряженных компонентов смесей. Нанесение проводящего углеродного слоя на поверхность пор является перспективным для создания мембран с управляемой ионной селективностью.
A novel type of ion-selective membranes based on NafenTM alumina nanofibers covered with carbon is proposed. The membranes are produced by filtration of Nafen nanofiber suspension through a porous support followed by drying and sintering. A thin carbon layer (up to 2 nm) is deposited on the nanofibers with the help of chemical vapor deposition (CVD). Its formation is confirmed by the results of Raman spectroscopy and visually observed in TEM images. According to low temperature nitrogen adsorption experiments, the formation of carbon layer leads to decreasing pore size (the maximum of pore size distribution shifts from 28 to 16 nm) and the corresponding decrease of porosity (from 75 to 62%) and specific surface area (from 146 to 107 m2 g–1). The measurement of membrane potential in an electrochemical cell shows that the deposition of carbon on the membrane results in high ionic selectivity. In an aqueous KCl solution, the membranes display high anion–selectivity with transference numbers 0.94 for anion and 0.06 for cation. The fixed charge density of membrane is determined by fitting the experimental data with the help of Teorell–Meyer–Sievers model. It is found that the density of fixed membrane charge increases with increasing the electrolyte concentration. The potential applications of produced membranes include nano- and ultrafiltration as well as separation of charged species in mixtures. The formation of conductive carbon layer on the pore surface can be employed for producing membranes with switchable ion-transport selectivity. Keywords: alumina nanofiber, membrane, chemical vapor deposition, carbon, membrane potential measurement, ionic permselectivity, Teorell–Meyer–Sievers model

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Держатели документа:
Институт вычислительного моделирования СО РАН, Академгородок 50-44, Красноярск, Россия
Институт химии и химической технологии СО РАН, Академгородок 50-24, Красноярск, Россия
Красноярский научный центр СО РАН, Академгородок 50, Красноярск, Россия
Национальный исследовательский университет “МИЭТ”, Площадь Шокина, 1, Зеленоград, Москва, Россия

Доп.точки доступа:
Лебедев, Д.В.; Шиверский, А.В.; Симунин, М.М.; Солодовниченко, В.С.; Парфенов, В.А.; Быканова, В.В.; Хартов, С.В.; Рыжков, И.И.

/ I. I. Ryzhkov [et al.] // Chemical Engineering Transactions : Italian Association of Chemical Engineering - AIDIC, 2017. - Vol. 60. - P253-258, DOI 10.3303/CET1760043 . -
Аннотация: A novel type of ion-selective membranes, which combine the advantages of ceramic nanofibrous media with good electrical conductivity, is proposed. The membranes are produced from Nafen alumina nanofibers (diameter around 10 nm) by filtration of nanofiber suspension through a porous support followed by drying and sintering. Electrical conductivity is achieved by depositing a thin carbon layer on the nanofibers by CVD. Raman spectroscopy and TEM are used to confirm the carbon structure formation. The average pore size determined by low temperature nitrogen adsorption experiments lies in the range 15-30 nm. Measurements of membrane potential show that the carbon coated membranes acquire high ionic selectivity (transference numbers 0.94 for anion and 0.06 for cation in aqueous KCl). The fixed membrane charge is determined by fitting the experimental data to Teorell-Meyer-Sievers and Space-charge models. © 2017, AIDIC Servizi S.r.l.

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Держатели документа:
Institute of Computational Modelling SB RAS, Akademgorodok 50-44, Krasnoyarsk, Russian Federation
Molecular Electronics Department KSC SB RAS, Akademgorodok 50-44, Krasnoyarsk, Russian Federation
National Research University of Electronic Technology, MIET, Shokin square 1, Zelenograd, Moscow, Russian Federation
Institute of Chemistry and Chemical Technology SB RAS, Akademgorodok 50-24, Krasnoyarsk, Russian Federation

Доп.точки доступа:
Ryzhkov, I. I.; Lebedev, D. V.; Solodovnichenko, V. S.; Shiverskiy, A. V.; Simunin, M. M.; Parfenov, V. A.

/ V. S. Solodovnichenko [et al.] // Adv. Eng. Mater. - 2017. - Vol. 19, Is. 11. - Ст. 1700244, DOI 10.1002/adem.201700244. - Cited References:60. - This work is supported by the Russian Science Foundation, Project 15-19-10017. The physicochemical analysis of materials was carried out on equipment of Krasnoyarsk Scientific Center of Shared Facilities SB RAS. . - ISSN 1438-1656. - ISSN 1527-2648РУБ Materials Science, Multidisciplinary

Аннотация: The authors propose a novel type of ion-selective membranes, which combine the advantages of ceramic nanofibrous media with good electrical conductivity. The membranes are produced from Nafen alumina nanofibers (diameter around 10nm) by filtration of nanofiber suspension through a porous support followed by drying and sintering. Electrical conductivity is achieved by depositing a thin carbon layer on the nanofibers by chemical vapor deposition (CVD). Raman and FTIR spectroscopy, X-ray fluorescence analysis, and TEM are used to confirm the carbon structure formation. The deposition of carbon leads to decreasing porosity (from 75 to 62%) and specific surface area (from 146 to 107m(2) g(-1)) of membranes, while the pore size distribution maximum shifts from 28 to 16nm. Measurements of membrane potential in an electrochemical cell show that the carbon coated membranes acquire high ionic selectivity (transference numbers 0.94 for anion and 0.06 for cation in aqueous KCl). Fitting the membrane potential data by the Teorell-Meyer-Sievers model shows that the fixed membrane charge increases proportionally with increasing electrolyte concentration. The carbon coated membranes are ideally polarizable for applied voltages from -0.5 to +0.8V. The potential applications of produced membranes include nano- and ultrafiltration, separation of charged species, and switchable ion-transport selectivity.

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Держатели документа:
Inst Computat Modeling SB RAS, Akademgorodok 50-44, Krasnoyarsk, Russia.
Fed Res Ctr KSC SB RAS, Akademgorodok 50, Krasnoyarsk, Russia.
Natl Res Univ Elect Technol MIET, Shokin Sq 1, Moscow, Russia.
Inst Chem & Chem Technol SB RAS, Akademgorodok 50-24, Krasnoyarsk, Russia.

Доп.точки доступа:
Solodovnichenko, Vera S.; Lebedev, Denis V.; Bykanova, Victoria V.; Shiverskiy, Alexey V.; Simunin, Mikhail M.; Parfenov, Vladimir A.; Ryzhkov, Ilya I.; Russian Science Foundation [15-19-10017]

/ V. E. Zalizniak, O. A. Zolotov, I. I. Ryzhkov // J. Appl. Mech. Tech. Phys. - 2018. - Vol. 59, Is. 1. - P41-51, DOI 10.1134/S0021894418010066. - Cited References:32. - This work was supported by the Russian Science Foundation (Grant No. 15-19-10017). The calculations were performed at the Center of High-Performance Calculations of the Siberian Federal University. . - ISSN 0021-8944. - ISSN 1573-8620РУБ Mechanics + Physics, Applied

Аннотация: A model of ionic solutions is proposed which can be used to calculate aqueous salt solutions in different nanostructures. The interaction potential of the model includes the Lennard-Jones potential and angularly averaged dipole-dipole and ion-dipole interactions. Lennard-Jones potential parameters for different ions are obtained. Characteristics of aqueous solutions at different salt concentrations are calculated using the molecular dynamics method. It is shown that the calculated values of the hydration shells of ions parameters are in good agreement with the theoretical and experimental data at a salt concentration of 1 mol/kg. The computational scheme used in the calculations is described. It is shown that calculations using the proposed model require less computing resources compared with the standard models of ionic solutions.

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Держатели документа:
Siberian Fed Univ, Inst Math & Fundamental Informat, Krasnoyarsk 660041, Russia.
Russian Acad Sci, Inst Computat Modeling, Siberian Branch, Krasnoyarsk 660036, Russia.

Доп.точки доступа:
Zalizniak, V. E.; Zolotov, O. A.; Ryzhkov, I. I.; Russian Science Foundation [15-19-10017]

/ D. V. Lebedev [et al.] // Pet. Chem. - 2018. - Vol. 58, Is. 6. - P474-481, DOI 10.1134/S0965544118060075. - Cited References:32. - This work was supported by the Russian Science Foundation, project no. 15-19-10017. The instrumental analysis of the materials was conducted at the Center for collective use of the Federal Research Center Krasnoyarsk Scientific Center of the Siberian Branch of the Russian Academy of Sciences. . - ISSN 0965-5441. - ISSN 1555-6239РУБ Chemistry, Organic + Chemistry, Physical + Energy & Fuels + Engineering,

Аннотация: The effect of an external electric field on the ionic conductivity and selective properties of ceramic membranes based on alumina nanofibers coated with a conductive carbon layer has been studied. It has been shown that the membranes are ideally polarizable in the polarizing voltage range of -500 to +500 mV and, therefore, can be used for implementing switchable ionic selectivity. Experiments have revealed that the membrane resistance decreases with a change in the applied potential from 0 to +/- 500 mV. It has been shown that the membrane selectivity can be switched from anion to cation by varying the external potential. The surface charge density of the membranes has been determined in terms of the Teorell-Meyer-Sievers model according to the experimental measurements of the membrane potential.

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Держатели документа:
Russian Acad Sci, Siberian Branch, Krasnoyarsk Sci Ctr, Inst Computat Modeling, Krasnoyarsk 660036, Russia.
St Petersburg State Univ, Inst Chem, St Petersburg 198504, Russia.
Siberian Fed Univ, Krasnoyarsk 660041, Russia.

Доп.точки доступа:
Lebedev, D. V.; Solodovnichenko, V. S.; Simunin, M. M.; Ryzhkov, I. I.; Russian Science Foundation [15-19-10017]

/ V. E. Zalizniak, O. A. Zolotov, I. I. Ryzhkov // J. Appl. Mech. Tech. Phys. - 2018. - Vol. 59, Is. 2. - P387, DOI 10.1134/S0021894418020256 . - ISSN 0021-8944
Аннотация: In the original publication, there are several misprints. 1. The author’s affilation was misspelled. It should read “V. E. Zalizniaka,b, O. A. Zolotova,b, and I. I. Ryzhkova,b” instead of “V. E. Zalizniaka,b, O. A. Zolotova,b, and I. I. Ryzhkovb.” 2. In Abstract, it should read “It is shown that the calculated parameters of ions hydration shells are in good agreement with the theoretical and experimental data at salt concentrations up to 1 mol/kg” instead of “It is shown that the calculated values of the hydration shells of ions parameters are in good agreement with the theoretical and experimental data at a salt concentration of 1 mol/kg.” 3. In Introduction (page 41, second paragraph), it should read “The intermolecular interaction between two water molecules is computed using the Lennard-Jones potential with just a single interaction point per molecule” instead of “Interaction of water molecules is described by the Lennard-Jones potential.” 4. In Section 3.4 (page 46, second paragraph), it should read “The temperature dependence of salt solutions density was investigated in [26] using the interaction potential based on the SPC/E water model” instead of “The temperature dependence of the density of the salt solutions of was investigated in [26] using the interaction potential based on the SPC/E water model.” 5. In Conclusions (page 49, second paragraph), it should read “The proposed interaction potential can be used in large-scale to model flows of ionic solutions in nanostructures” instead of “The proposed interaction potential can be in large-scale calculations to model flows of ionic solutions in nanostructures.” 6. In third paragraph, it should read “The calculations were performed at the Center of High-Performance Computing of the Siberian Federal University” instead of “The calculations were performed at the Center of High- Performance Calculations of the Siberian Federal University.”. © 2018, Pleiades Publishing, Ltd.

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Держатели документа:
Institute of Mathematics and Fundamental Informatics, Siberian Federal University, Krasnoyarsk, Russian Federation
Institute of Computational Modeling, Siberian Branch, Russian Academy of Sciences, Krasnoyarsk, Russian Federation

Доп.точки доступа:
Zalizniak, V. E.; Zolotov, O. A.; Ryzhkov, I. I.

[Текст] : статья / Д. В. Лебедев [и др.] // Мембраны и мембранные технологии. - 2018. - Т. 8, № 3. - С. 157-165, DOI 10.1134/S2218117218030070 . - ISSN 2218-1172
   Перевод заглавия: The Influence of Electric Field on The Ion Transport on Nanoporous Membranes with Conductive Surface

УДК

66.081.6

Аннотация: В работе исследуется влияние внешнего электрического поля на ионную проводимость и селективные свойства керамических мембран на основе нановолокон оксида алюминия, покрытых проводящим слоем углерода. Показано, что мембраны являются идеально поляризуемыми в области поляризующих напряжений от –500 до +500 мВ, что позволяет использовать их для реализации управляемой ионной селективности. Экспериментально установлено, что сопротивление мембраны уменьшается при изменении приложенного к ней потенциала от 0 до ±500 мВ. Продемонстрирована возможность изменения селективности мембраны от аниона к катиону в зависимости от внешнего потенциала. На основе экспериментальных измерений мембранного потенциала определена поверхностная плотность заряда мембран с помощью модели Теорелла–Мейера–Сиверса.
In this work, we investigate the influence of external electric field on the ionic conductivity and selectivity of ceramic membranes based on alumina nanofibers covered with conductive carbon layer. It is shown that the membranes are ideally polarizable in the range of voltages from –500 mV to +500 mV, which makes them suitable candidates for realizing switchable ionic selectivity. It is found experimentally that the membrane resistance decreases with increasing the potential applied to the membrane from 0 to ±500 mV. The possibility of changing the membrane selectivity from anion to cation depending on the applied potential is demonstrated. The membrane surface charge density is determined from experimental measurements of membrane potential with the help of Teorell-Meyer-Sievers model. Keywords: ceramic membranes, nanopore, conductive surface, ionic selectivity, ionic conductivity, switchable ion transport

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Держатели документа:
Красноярский научный центр СО РАН
Санкт-Петербургский государственный университет, Институт химии, Университетский проспект, 26, Санкт-Петербург, Петергоф, 198504 Россия
Сибирский федеральный университет

Доп.точки доступа:
Лебедев, Д.В.; Lebedev D.V.; Солодовниченко, В.С.; Solodovnichenko V.S.; Симунин, М.М.; Simunin M.M.; Рыжков, И.И.; Ryzhkov I.I.

/ I. I. Ryzhkov, A. S. Vyatkin, M. I. Medvedeva // J. Sib. Fed. Univ. Math. Phys. - 2019. - Vol. 12, Is. 5. - P579-589, DOI 10.17516/1997-1397-2019-12-5-579-589 . - ISSN 1997-1397
Аннотация: The impact of potential applied to the conductive surface of nanoporous membrane on the membrane potential at zero current is investigated theoretically on the basis of two–dimensional Space–charge model. The membrane separates two reservoirs with different salt concentrations. It is shown that the variation of applied potential from negative to positive values results in the continuous change of membrane selectivity from cation to anion. For equal ion diffusion coefficients, the dependence of membrane potential on the applied potential is an odd function, while for different ion diffusion coefficients it is shifted along the applied potential axis due to contribution of diffusion potential enhanced by the induced charge effect. The decrease of pore radius results in the increase of ionic selectivity and steep transition between cation– selective and anion–selective states when the applied potential is changing. © Siberian Federal University.

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Держатели документа:
Institute of Computational Modelling SB RAS, Akademgorodok, 50–44, Krasnoyarsk, 660036, Russian Federation
Siberian Federal University, Svobodny, 79, Krasnoyarsk, 660041, Russian Federation

Доп.точки доступа:
Ryzhkov, I. I.; Vyatkin, A. S.; Medvedeva, M. I.

/ I. I. Ryzhkov, A. S. Vyatkin, M. I. Medvedeva // J. Sib. Fed. Univ.-Math. Phys. - 2019. - Vol. 12, Is. 5. - P579-589, DOI 10.17516/1997-1397-2019-12-5-579-589. - Cited References:32. - The reported study was funded by Russian Foundation for Basic Research, Government of Krasnoyarsk Territory, Krasnoyarsk Regional Fund of Science, to the research project 18-48-242011 "Mathematical modelling of synthesis and ionic transport properties of conductive nanoporous membranes". . - ISSN 1997-1397. - ISSN 2313-6022РУБ Mathematics

Аннотация: The impact of potential applied to the conductive surface of nanoporous membrane on the membrane potential at zero current is investigated theoretically on the basis of two-dimensional Space-charge model. The membrane separates two reservoirs with different salt concentrations. It is shown that the variation of applied potential from negative to positive values results in the continuous change of membrane selectivity from cation to anion. For equal ion diffusion coefficients, the dependence of membrane potential on the applied potential is an odd function, while for different ion diffusion coefficients it is shifted along the applied potential axis due to contribution of diffusion potential enhanced by the induced charge effect. The decrease of pore radius results in the increase of ionic selectivity and steep transition between cation- selective and anion-selective states when the applied potential is changing.

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Держатели документа:
Inst Computat Modelling SB RAS, Akademgorodok 50-44, Krasnoyarsk 660036, Russia.
Siberian Fed Univ, Svobodny 79, Krasnoyarsk 660041, Russia.

Доп.точки доступа:
Ryzhkov, Ilya I.; Vyatkin, Anton S.; Medvedeva, Maria, I; Russian Foundation for Basic Research, Government of Krasnoyarsk Territory, Krasnoyarsk Regional Fund of Science [18-48-242011]