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Publications in Math-Net.Ru |
Citations |
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2023 |
1. |
V. S. Bystrov, E. V. Paramonova, S. V. Filippov, L. A. Avakyan, M. V. Chaikina, N. V. Eremina, S. V. Makarova, N. V. Bulina, “Zinc-substituted structures of hydroxyapatite: Modeling and experiment”, Mat. Biolog. Bioinform., 18:2 (2023), 580–601 |
2. |
I. V. Likhachev, V. S. Bystrov, S. V. Filippov, “Assembly of a diphenylalanine peptide nanotube by molecular dynamics methods”, Mat. Biolog. Bioinform., 18:1 (2023), 251–266 |
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2021 |
3. |
V. S. Bystrov, S. V. Filippov, “Computer modeling and numerical studies of peptide nanotubes based on diphenylalanine”, Keldysh Institute preprints, 2021, 078, 54 pp. |
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4. |
I. V. Likhachev, V. S. Bystrov, “Assembly of a phenylalanine nanotube by the use of molecular dynamics manipulator”, Mat. Biolog. Bioinform., 16:2 (2021), 244–255 |
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2020 |
5. |
V. S. Bystrov, V. M. Fridkin, “Two-dimensional ferroelectrics and homogeneous switching. On the 75th anniversary of the Landau–Ginzburg theory of ferroelectricity”, UFN, 190:11 (2020), 1217–1224 ; Phys. Usp., 63:11 (2020), 1140–1147 |
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2019 |
6. |
V. S. Bystrov, P. S. Zelenovskiy, A. S. Nuraeva, S. Kopyl, O. A. Zhulyabina, V. A. Tverdislov, “Chiral peculiar properties of self-organization of diphenylalanine peptide nanotubes: modeling of structure and properties”, Mat. Biolog. Bioinform., 14:1 (2019), 94–125 |
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2017 |
7. |
A. V. Bystrova, E. V. Paramonova, I. K. Bdikin, M. V. Silibin, D. V. Karpinsky, X. J. Meng, V. S. Bystrov, “Computer aided molecular modeling of the piezoelectric properties of ferroelectric composites on the base of polyvinylidene fluoride with graphene and graphene oxide”, Mat. Biolog. Bioinform., 12:2 (2017), 466–486 |
8. |
V. S. Bystrov, “Computational studies of the hydroxyapatite nanostructures, peculiarities and properties”, Mat. Biolog. Bioinform., 12:1 (2017), 14–54 |
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2015 |
9. |
V. S. Bystrov, E. V. Paramonova, A. V. Bystrova, V. E. Gevorkyan, X. J. Meng, B. B. Tian, J. L. Wang, L. A. Avakyan, “Analysis of the computational and experimental studies of the polarization switching in the PVDF and P(VDF-TrFE) ferroelectric films at the nanoscale”, Mat. Biolog. Bioinform., 10:2 (2015), 372–386 |
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10. |
V. E. Gevorkyan, E. V. Paramonova, L. A. Avakyan, V. S. Bystrov, “Computer modeling and molecular dynamics of polarization switching in the ferroelectric films PVDF and P(VDF-TrFE) on nanoscale”, Mat. Biolog. Bioinform., 10:1 (2015), 131–153 |
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2014 |
11. |
V. S. Bystrov, V. V. Êamyshlov, “Ànalytical research of nonlinear properties of ferroelectrics”, Izvestiya VUZ. Applied Nonlinear Dynamics, 22:2 (2014), 77–94 |
12. |
A. V. Bystrova, Yu. D. Dekhtyar, A. I. Popov, V. S. Bystrov, “Modeling and Synchrotron Data Analysis of Modified Hydroxyapatite Structure”, Mat. Biolog. Bioinform., 9:1 (2014), 171–182 |
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13. |
D. A. Turchenkov, V. S. Bystrov, “Experimental and Theoretical Methods of Study of Ionic Channels”, Mat. Biolog. Bioinform., 9:1 (2014), 112–148 |
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2011 |
14. |
V. S. Bystrov, E. V. Paramonova, Yu. D. Dekhtyar, A. Katashev, N. Polyaka, A. V. Bystrova, A. V. Sapronova, V. M. Fridkin, G. Klim, A. L. Kholkin, “Computational studies of PVDF and P(VDF-TrFE) nanofilms polarization during phase transition revealed by emission spectroscopy”, Mat. Biolog. Bioinform., 6:2 (2011), 273–297 |
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2009 |
15. |
V. S. Bystrov, N. K. Bystrova, E. V. Paramonova, Yu. D. Dekhtyar, “Interaction of charged hydroxyapatite and living cells. I. Hydroxyapatite polarization properties”, Mat. Biolog. Bioinform., 4:2 (2009), 7–11 |
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