A biomimetic approach to the creation of polymer materials with improved tribological properties

A. A. Grigoriev; E. A. Isaev; D. V. Pervukhin; V. N. Petrushin; F. A. Doronin; Yu. V. Rudyak; G. O. Rytikov; V. G. Nazarov

Geodesic

Parcourir par

A biomimetic approach to the creation of polymer materials with improved tribological properties

A. A. Grigoriev ; E. A. Isaev ; D. V. Pervukhin ; V. N. Petrushin ; F. A. Doronin ; Yu. V. Rudyak ; G. O. Rytikov ; V. G. Nazarov

Matematičeskaâ biologiâ i bioinformatika, Tome 19 (2024) no. 1, pp. 1-14

Voir la notice de l'article provenant de la source Math-Net.Ru

Résumé

The work is devoted to the use of methods of applied mathematics and statistics for the formalization and mathematical modeling of the structure of shark skin as a prototype of new polymer materials for shipbuilding purposes. A technique for mathematical modeling of biological objects is described, and a method for using a biomimetic approach for the design of planar composite polymer materials with improved lyophilic adhesion properties is proposed. Because of studying images of shark skin obtained using high-resolution optical (HRO) and scanning electron (SEM) microscopy, we found that its texture is anisotropic. Quantitative analysis of BOM and SEM images made it possible to rationalize the choice of synthetic digital models intended for simulation prototyping of maximally and minimally texturally isotropic polymer samples using 3D printing and gas-phase surface modification.

Export
Comment citer

@article{MBB_2024_19_1_a0,
     author = {A. A. Grigoriev and E. A. Isaev and D. V. Pervukhin and V. N. Petrushin and F. A. Doronin and Yu. V. Rudyak and G. O. Rytikov and V. G. Nazarov},
     title = {A biomimetic approach to the creation of polymer materials with improved tribological properties},
     journal = {Matemati\v{c}eska\^a biologi\^a i bioinformatika},
     pages = {1--14},
     publisher = {mathdoc},
     volume = {19},
     number = {1},
     year = {2024},
     language = {ru},
     url = {http://geodesic.mathdoc.fr/item/MBB_2024_19_1_a0/}
}

TY  - JOUR
AU  - A. A. Grigoriev
AU  - E. A. Isaev
AU  - D. V. Pervukhin
AU  - V. N. Petrushin
AU  - F. A. Doronin
AU  - Yu. V. Rudyak
AU  - G. O. Rytikov
AU  - V. G. Nazarov
TI  - A biomimetic approach to the creation of polymer materials with improved tribological properties
JO  - Matematičeskaâ biologiâ i bioinformatika
PY  - 2024
SP  - 1
EP  - 14
VL  - 19
IS  - 1
PB  - mathdoc
UR  - http://geodesic.mathdoc.fr/item/MBB_2024_19_1_a0/
LA  - ru
ID  - MBB_2024_19_1_a0
ER  -

%0 Journal Article
%A A. A. Grigoriev
%A E. A. Isaev
%A D. V. Pervukhin
%A V. N. Petrushin
%A F. A. Doronin
%A Yu. V. Rudyak
%A G. O. Rytikov
%A V. G. Nazarov
%T A biomimetic approach to the creation of polymer materials with improved tribological properties
%J Matematičeskaâ biologiâ i bioinformatika
%D 2024
%P 1-14
%V 19
%N 1
%I mathdoc
%U http://geodesic.mathdoc.fr/item/MBB_2024_19_1_a0/
%G ru
%F MBB_2024_19_1_a0

A. A. Grigoriev; E. A. Isaev; D. V. Pervukhin; V. N. Petrushin; F. A. Doronin; Yu. V. Rudyak; G. O. Rytikov; V. G. Nazarov. A biomimetic approach to the creation of polymer materials with improved tribological properties. Matematičeskaâ biologiâ i bioinformatika, Tome 19 (2024) no. 1, pp. 1-14. http://geodesic.mathdoc.fr/item/MBB_2024_19_1_a0/

Bibliographie
Cité par

[1] M. Kazemi, E. H. Fini, “State of the art in the application of functionalized waste polymers in the built environment”, Resources, Conservation and Recycling, 177 (2022), 105967 | DOI | DOI

[2] A. A. Hasseb, N. D.T. Abdel Ghani, O. R. Shehab, R. M. El Nashar, “Application of molecularly imprinted polymers for electrochemical detection of some important biomedical markers and pathogens”, Current Opinion in Electrochemistry, 31 (2022), 100848 | DOI | DOI

[3] A. Gbadamosi, S. Patil, M. S. Kamal, A. A. Adewunmi, A. S. Yusuff, A. Agi, J. Oseh, “Application of polymers for chemical enhanced oil recovery: a review”, Polymers, 14:7 (2022) | DOI | DOI

[4] X. Cao, Z. Ye, X. Li, Y. J. Xu, Y. Liu, “Synthesis and application of magnetic surface molecularly imprinted polymers in selective solid-phase extraction of epoxy triglyceride from deep frying oil”, Food Control, 137 (2022), 108896 | DOI | DOI

[5] E. A. Isaev, F. A. Doronin, A. G. Evdokimov, D. V. Pervukhin, Yu. V. Rudyak, G. O. Rytikov, V. V. Kornilov, V. G. Nazarov, “Kolichestvennaya otsenka razvitiya kolonii mikromitsetov na poverkhnostyakh polimerov i kompozitov na ikh osnove”, Matematicheskaya biologiya i bioinformatika, 16:2 (2021), 367–379 | DOI | DOI

[6] R. Po, A. Bernardi, A. Calabrese, C. Carbonera, G. Corso, A. Pellegrino, “From Lab to Fab: how must the polymer solar cell materials design change? An industrial perspective”, Energy Environmental Science, 7:3 (2014), 925–943 | DOI | DOI

[7] E. S. Pravada, L. R. Lyusova, S. G. Karpova, E. I. Antman, S. V. Kotova, “Vliyanie strukturno-dinamicheskikh parametrov na adgezionnye svoistva 3,4-poliizoprena”, Kauchuk i rezina, 81:4 (2022), 190–193

[8] L. Tan, B. Tan, “Hypercrosslinked porous polymer materials: design, synthesis, and applications”, Chemical Society Reviews, 46:11 (2017), 3322–3356 | DOI | DOI

[9] E. V. Korolev, V. A. Smirnov, A. I. Albakasov, A. S. Inozemtsev, “Nekotorye aspekty proektirovaniya sostavov mnogokomponentnykh kompozitsionnykh materialov”, Nanotekhnologii v stroitelstve: nauchnyi internet-zhurnal, 3:6 (2011), 32–43

[10] V. S. Lesovik, L. Kh. Zagorodnyuk, I. L. Chulkova, A. D. Tolstoi, A. A. Volodchenko, “Srodstvo struktur kak teoreticheskaya osnova proektirovaniya kompozitov buduschego”, Stroitelnye materialy, 2015, no. 9, 18–22

[11] F. V. Grechnikov, V. Yu. Aryshenskii, Ya. A. Erisov, “Proektirovanie optimalnoi kristallografii struktury konstruktsionnykh materialov”, Izvestiya Samarskogo nauchnogo tsentra Rossiiskoi akademii nauk, 20:4-1(84) (2018), 5–12

[12] V. A. Babeshko, O. V. Evdokimova, O. M. Babeshko, I. V. Ryadchikov, “Metod proektirovaniya neodnorodnykh materialov i blochnykh konstruktsii”, Doklady Akademii nauk, 482:4 (2018), 398–402 | DOI | DOI

[13] D. A. Trofimov, S. I. Shalgunov, I. D. Simonov-Emelyanov, “Issledovanie fiziko mekhanicheskikh kharakteristik modifitsirovannykh epoksidnykh matrits i armirovannykh plastikov s ispolzovaniem sovremennykh vychislitelnykh kompleksov dlya raschetov”, Plasticheskie massy, 2023, no. 1-2, 39–41

[14] G. A. Tarnavskii, V. S. Anischik, “Instrumentarii nanomod kompyuternoi podderzhki proektirovaniya nanostrukturirovannykh poluprovodnikovykh materialov”, Vychislitelnye metody i programmirovanie, 10:1 (2009), 34–50

[15] A. N. Bobryshev, D. E. Zharin, L. N. Shafigullin, M. I. Gumerov, “Sistema avtomatizirovannogo proektirovaniya polimernykh napolnennykh kompozitsionnykh materialov spetsialnogo naznacheniya”, Kuznechno-shtampovochnoe proizvodstvo. Obrabotka materialov davleniem, 2009, no. 8, 9–16

[16] V. V. Shevelev, “Prognozirovanie dolgovechnosti puchka volokon pri odnoosnom rastyazhenii na osnove termofluktuatsionnoi modeli ikh khrupkogo razrusheniya”, Prikladnaya mekhanika i tekhnicheskaya fizika, 64:5 (381) (2023), 194–204 | Zbl | Zbl

[17] E. M. Kartashov, “Obobschennye modelnye predstavleniya teorii teplovogo udara”, Matematicheskoe modelirovanie, 35:8 (2023), 14–30 | DOI | Zbl | DOI | Zbl

[18] K. A. Brekhova, I. D. Simonov-Emelyanov, A. A. Pykhtin, “Proektirovanie struktury i sostavov stoikikh k goreniyu polimernykh kompozitsionnykh materialov s napolnitelyami-antipirenami na osnove gidroksida magniya”, Tonkie khimicheskie tekhnologii, 18:2 (2023), 109–122 | DOI | DOI

[19] A. G. Dementeva, V. V. Kovriga, “Vliyanie zaschitnogo diffuzionnogo gazovogo potoka na svoistva polietilenovykh gazoprovodov”, Plasticheskie massy, 2023, no. 1-2, 47

[20] E. A. Deshevaya, M. V. Gusarov, V. A. Tverskoi, “Morfologiya i antimikrobnye svoistva kompozitsii polivinilbutiralya i etilenpropilenovogo kauchuka s aromaticheskimi spirtami”, Aviakosmicheskaya i ekologicheskaya meditsina, 56:3 (2022), 54–60

[21] S. V. Polunin, I. Yu. Gorbunova, M. L. Kerber, I. A. Kryuchkov, P. A. Morozova, T. P. Kravchenko, “Vliyanie kardovogo polisulfona na vyazkouprugie svoistva epoksidnykh polimerov. Vse materialy”, Entsiklopedicheskii spravochnik, 2023, no. 2, 38–41

[22] B. Bhushan, “Biomimetics inspired surfaces for drag reduction and oleophobicity/philicity”, Beilstein Journal of Nanotechnology, 2:1 (2011), 66–84 | DOI | DOI

[23] G. D. Bixler, B. Bhushan, “Fluid drag reduction and efficient self-cleaning with rice leaf and butterfly wing bioinspired surfaces”, Nanoscale, 5:17 (2013), 7685–7710 | DOI | DOI

[24] E. A. Isaev, D. V. Pervukhin, V. V. Kornilov, P. A. Tarasov, A. A. Grigorev, Yu. V. Rudyak, G. O. Rytikov, V. G. Nazarov, “Kolichestvennaya otsenka zavisimosti adgezii trombotsitov k ftorirovannomu polietilenu ot strukturnykh kharakteristik ego poverkhnosti”, Matematicheskaya biologiya i bioinformatika, 14:2 (2019), 420–429 | DOI | DOI

[25] G. D. Bixler, B. Bhushan, “Bioinspired rice leaf and butterfly wing surface structures combining shark skin and lotus effects”, Soft Matter, 8:44 (2012), 11271–11284 | DOI | DOI

[26] V. B. Damodaran, S. N. Murthy, “Bio-inspired strategies for designing antifouling biomaterials”, Biomaterials Research, 20:1 (2016), 18 | DOI | DOI

[27] A. Jaggessar, H. Shahali, P. K.D. V. Yarlagadda, A. Mathew, “Bio-mimicking nano and micro-structured surface fabrication for antibacterial properties in medical implants”, Journal of Nanobiotechnology, 15:1 (2017), 64 | DOI | DOI

[28] B. Li, Y. J. Pang, Y. X. Cheng, X. M. Zhu, “Collaborative optimization for ring-stiffened composite pressure hull of underwater vehicle based on lamination parameters”, International Journal of Naval Architecture and Ocean Engineering, 9:4 (2017), 373–381 | DOI | MR | DOI | MR

[29] Yu. Li, L. Zhang, Ch. Zhang, Zh. Zhang, L. Liu, “Bioinspired antifouling fe-based amorphous coating via killing-resisting dual surface modifications”, Scientific Reports, 12:1 (2022), 1–10 | DOI | MR | DOI | MR

[30] J. Ferrario, S. Caronni, A. Occhipinti-Ambrogi, A. Marchini, “Role of commercial harbours and recreational marinas in the spread of non-indigenous fouling species”, Biofouling, 33:8 (2017), 651–660 | DOI | DOI

[31] D. Quere, “Wetting and roughness”, Annual Review of Materials Research, 38 (2008), 71–99 | DOI | DOI

[32] N. S. Serkhacheva, K. A. Ryzhikov, N. I. Prokopov, A. V. Plutalova, A. V. Bol'shakova, E. V. Chernikova, “Seeded raft polymerization of styrene for the synthesis of stable dispersions of amphiphilic block copolymers and composite nanoparticles”, Polymer Science, Series B, 64 (2022), 124–136 | DOI | DOI

[33] A. A. Zuev, L. R. Lyusova, L. A. Kovaleva, N. P. Boreiko, “The influence of filler on the properties of resin-metal compounds”, Polymer Science, Series D, 15:2 (2022), 260–263 | DOI | MR | DOI | MR

[34] S. Li, S. Q. Zhang, L. Shen, Q. Liu, J. B. Ma, W. Lv, Y. B. He, Q. H. Yang, “Progress and perspective of ceramic/polymer composite solid electrolytes for lithium batteries”, Advanced Science, 7:5 (2020), 1903088 | DOI | DOI

[35] N. D.H. Seuyep, D. Szopinski, G. A. Luinstra, P. Theato, “Post-polymerization modification of reactive polymers derived from vinylcyclopropane: a poly(vinylcyclopropane) derivative with physical gelation and ucst behaviour in ethanol-water mixtures”, Polymer Chemistry, 5:19 (2014), 5823–5828 | DOI | DOI

[36] B. Wang, X. Wang, H. Zheng, Y. C. Lam, “Surface wettability modification of cyclic olefin polymer by direct femtosecond laser irradiation”, Nanomaterials, 5:3 (2015), 1442–1453 | DOI | DOI

[37] X. Liu, G. Yang, V. Lipik, “Permanent water repellent chemical modification of cotton fabric with reagents containing aromatic rings”, Fibers and Polymers, 20:1 (2019), 51–56 | DOI | DOI

[38] R. Wang, Y. Yang, Y. Lu, M. Zhang, “A simple modification to improve the immunity of linear electromagnetic actuators against disturbing magnetic field”, Journal of Magnetism and Magnetic Materials, 550 (2022), 169125 | DOI | DOI

[39] A. P. Vasilev, T. S. Struchkova, L. A. Nikiforov, A. A. Okhlopkova, J. H. Cho, P. N. Grakovich, E. L. Shim, “Mechanical and tribological properties of polytetrafluoroethylene composites with carbon fiber and layered silicate fillers”, Molecules, 24:2 (2019), 0224 | DOI | DOI

[40] V. V. Klimov, O. V. Kolyaganova, E. V. Bryuzgin, A. V. Navrotsky, I. A. Novakov, “Effect of the composition of copolymers based on glycidyl methacrylate and fluoroalkyl methacrylates on the free energy and lyophilic properties of the modified surface”, Polymers, 14:10 (2022), 1960 | DOI | DOI

[41] N. Annabi, E. Shirzaei Sani, R. Portillo-Lara, M. M. Fares, D. Rana, J. L. Gifford, S. M. Mithieux, A. S. Weiss, “Engineering a sprayable and elastic hydrogel adhesive with antimicrobial properties for wound healing”, Biomaterials, 139 (2017), 229–243 | DOI | DOI

[42] X. Yu, Y. Zhao, Y. Feng, X. Hu, J. Liu, X. Wang, M. Wu, H. Dong, Y. Liang, W. Wang, F. Tian, “Synthesis and performance characterization of a road coal dust suppressant with excellent consolidation, adhesion, and weather resistance”, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 639 (2022), 128334

[43] G. Barati Darband, M. Aliofkhazraei, S. Sokhanvar, A. Kaboli, S. Khorsand, “Science and engineering of superhydrophobic surfaces: review of corrosion resistance, chemical and mechanical stability”, Arabian Journal of Chemistry, 13:1 (2020), 1763–1802 | DOI | DOI

[44] A. Tyagi, R. S. Walia, Q. Murtaza, S. M. Pandey, P. K. Tyagi, B. Bajaj, “A critical review of diamond like carbon coating for wear resistance applications”, International Journal of Refractory Metals and Hard Materials, 78 (2019), 107–122 | DOI | DOI

[45] D. Sivkov, A. Mingaleva, O. Petrova, S. Isaenko, D. Bogachuk, R. Skandakov, V. Sivkov, S. Nekipelov, A. Ob'edkov, B. Kaverin, I. Vilkov, S. Gusev, “The structure and chemical composition of the cr and fe pyrolytic coatings on the mwcnts' surface according to nexafs and xps spectroscopy”, Nanomaterials, 10:2 (2020), 374 | DOI | DOI

[46] X. J. Shen, J. L. Wen, T. Q. Yuan, T. Chen, H. M. Wang, S. Sun, Q. Mei, F. Yue, R. C. Sun, “Structural and morphological transformations of lignin macromolecules during bio based deep eutectic solvent (des) pretreatment”, ACS Sustainable Chemistry and Engineering, 8:5 (2020), 2130–2137 | DOI | DOI

[47] G. O. Rytikov, F. A. Doronin, A. G. Evdokimov, V. G. Nazarov, M. A. Savel'ev, “An approach to structural and functional modeling of the surface morphology of materials based on fluorinated polymers”, Russian Journal of General Chemistry, 91:12 (2021), 2667–2672 | DOI | DOI

[48] G. O. Rytikov, F. A. Doronin, A. G. Evdokimov, Y. V. Rudyak, V. G. Nazarov, “The effect of morphological surface inhomogeneities on the mycological resistance of polymer films”, Protection of Metals and Physical Chemistry of Surfaces, 57:2 (2021), 422–431 | DOI | DOI

[49] V. V. Ivanov, O. V. Krivolapova, L. O. Belova, A. D. Kirilin, “Sravnenie aktivnosti olovoorganicheskikh soedinenii i sulfokisloty pri poluchenii sshitogo polietilena”, Plasticheskie massy, 2013, no. 2, 19–24

[50] V. G. Nazarov, V. P. Stolyarov, A. P. Kondratov, “Surface channel microstructures in polymer films for fluid transport”, Proceedings of the World Congress on Mechanical, Chemical, and Material Engineering. Proceedings of the World Congress on Mechanical, Chemical, and Material Engineering (MCM 2015), 2015, 242

[51] V. V. Pavlova, M. D. Sokolova, A. F. Fedorova, “Vliyanie soderzhaniya i prirody plastifikatora na svoistva butadien-nitrilnoi reziny”, Zhurnal Sibirskogo federalnogo universiteta. Seriya: Tekhnika i tekhnologii, 14:2 (2021), 222–232

[52] A. A. Olkhov, S. G. Karpova, S. Z. Rogovina, L. A. Zhorina, A. S. Kurnosov, A. L. Iordanskii, “Vliyanie ozona na strukturu biorazlagaemykh matrits na osnove smesei poli(3-gidroksibutirata), polilaktida i khitozana”, Materialovedenie, 2022, no. 4, 35–41

[53] V. A. Pogodin, A. N. Astapov, M. S. Eremkina, A. V. Babaytsev, L. N. Rabinskiy, “Investigation of the low-temperature oxidation effect on the structure and mechanical properties of C/C composite”, Nanoscience and Technology, 12:3 (2021), 29–46 | DOI | DOI

[54] T. Zhang, H. Lan, Sh. Yu, Ch. Huang, L. Du, W. Zhang, “High-temperature solid lubricant coating by plasma spraying using metal-metal clad powders”, Journal of Thermal Spray Technology, 26:6 (2017), 1268–1278 | DOI | DOI

[55] Guo S., Neoh K.G., Jańczewski D., Zhu X., Quintana R., He T., “Surface charge control for zwitterionic polymer brushes: tailoring surface properties to antifouling applications”, Journal of Colloid and Interface Science, 452 (2015), 43–53 | DOI | DOI

[56] V. K. Khoang, S. V. Reznichenko, S. V. Emelyanov, V. D. Doan, D. S. Reznichenko, “Issledovanie usilivayuschego deistviya dioksida kremniya iz risovoi shelukhi vetnama v elastomernykh materialakh na osnove nepolyarnykh kauchukov”, Kauchuk i rezina, 81:4 (2022), 178–183

[57] A. V. Baranov, “Techenie vyazkoi reagiruyuschei zhidkosti cherez poristyi napolnitel v ploskom kanale”, Plasticheskie massy, 2023, no. 1-2, 42–43

[58] A. L. Volynskii, L. M. Yarysheva, D. V. Bagrov, E. G. Rukhlya, A. Y. Yarysheva, N. F. Bakeev, V. G. Nazarov, V. P. Stolyarov, S. V. Tsypysheva, “Evaluation of the deformation strength properties of a fluorinated polymer layer on the surface of poly(ethylene terephthalate) films”, Doklady Physical Chemistry, 442:1 (2012), 5–7 | DOI | DOI

[59] V. I. Sevastyanov, E. A. Nemets, V. P. Stolyarov, V. A. Baranov, N. N. Bozhko, V. G. Nazarov, “Sravnitelnoe issledovanie vliyaniya nekotorykh metodov modifikatsii poverkhnosti plenok polietilena na vzaimodeistvie s komponentami krovi”, Perspektivnye materialy, 2010, no. 4, 41–48

[60] F. Doronin, G. Rytikov, A. Evdokimov, Yu. Rudyak, I. Taranets, V. Nazarov, “The effect of electro-induced multi-gas modification on polymer substrates' surface structure for additive manufacturing”, Processes, 11 (2023), 774 | DOI | DOI

[61] F. A. Doronin, Y. V. Rudyak, G. O. Rytikov, A. G. Evdokimov, V. G. Nazarov, “3D-printed planar microfluidic device on oxyfluorinated PET-substrate”, Polymer Testing, 99 (2021), 107209 | DOI | DOI

[62] F. A. Doronin, M. A. Savelev, I. P. Taranets, Yu. V. Rudyak, G. O. Rytikov, V. G. Nazarov, “Variatsionno-rotatsionnaya anizotropiya kak novyi podkhod k kolichestvennoi otsenke stepeni morfologicheskoi geterogennosti poverkhnosti polimernykh materialov”, Rossiiskii khimicheskii zhurnal, 65:4 (2021), 8–15 | DOI | MR | DOI | MR

[63] S. Liu, S. Sang, W. Wang, Y. Du, T. Wang, G. Wang, J. Ma, X. Wang, “FIB-SEM and X ray CT characterization of interconnected pores in high-rank coal formed from regional metamorphism”, Journal of Petroleum Science and Engineering, 148 (2017), 21–31 | DOI | DOI

[64] A. V. Markov, V. N. Lobanov, “Otsenka napryazhennogo sostoyaniya polikarbonatnykh monolitnykh listov optiko-polyarizatsionnymi metodami”, Tonkie khimicheskie tekhnologii, 17:1 (2022), 65–75 | DOI | DOI

[65] A. S. Orekhov, V. V. Klechkovskaya, S. V. Kononova, “Low-voltage scanning electron microscopy of multilayer polymer systems”, Crystallography Reports, 62:5 (2017), 710–715 | DOI | DOI

[66] V. N. Petrushin, Yu. V. Rudyak, G. O. Rytikov, V. G. Nazarov, “Postroenie bikriterialno dostovernykh empiricheskikh raspredelenii yarkostei pikselei pri kolichestvennom analize SEM izobrazhenii”, Izvestiya vysshikh uchebnykh zavedenii. Problemy poligrafii i izdatelskogo dela, 2017, no. 5, 3–14

[67] A. G. Evdokimov, F. A. Doronin, M. A. Savelev, G. O. Rytikov, V. G. Nazarov, “Matematicheskoe modelirovanie morfologicheskoi struktury poverkhnostno modifitsirovannykh polimernykh plenochnykh materialov”, Tekhnologii i materialy dlya ekstremalnykh uslovii (prognoznye issledovaniya i innovatsionnye razrabotki), materialy vserossiiskoi nauchnoi konferentsii, ed. B.F. Myasoedov, 2018, 216–220

[68] G. O. Rytikov, D. V. Pervoukhin, V. G. Nazarov, “A new approach to quantitative characterization of the material's surface morphological heterogeneity”, Lecture Notes in Civil Engineering, 210 (2022), 301–307 | DOI | DOI

[69] E. S. Kopachev, S. A. Nozdrachev, V. N. Petrushin, Yu. V. Rudyak, G. O. Rytikov, V. G. Nazarov, “Kompleksnyi metod kharakterizatsii izobrazhenii poverkhnostei polimernykh kompozitnykh materialov”, Fizicheskaya mezomekhanika, 18:6 (2015), 98–110

[70] S. A. Drozdov, V. G. Nazarov, S. A. Nozdrachev, Yu. V. Rudyak, G. O. Rytikov, “The polymer composites' morphological structure simulation”, Nanosystems: Physics, Chemistry, Mathematics, 8:1 (2017), 137–145 | DOI | DOI

[71] G. O. Rytikov, A. V. Dedov, Yu. V. Rudyak, V. G. Nazarov, “Avtomatizatsiya protsessa analiza SEM izobrazhenii poverkhnostnykh sloev voloknistykh materialov”, Izvestiya vysshikh uchebnykh zavedenii. Problemy poligrafii i izdatelskogo dela, 2017, no. 5, 15–24

[72] G. O. Rytikov, F. A. Doronin, A. G. Evdokimov, M. A. Savelev, V. G. Nazarov, “Podkhod k strukturno-funktsionalnomu modelirovaniyu morfologicheskoi struktury poverkhnosti materialov na osnove ftorirovannykh polimerov”, Rossiiskii khimicheskii zhurnal, 64:3 (2020), 63–68 | DOI | DOI

[73] G. O. Rytikov, F. A. Doronin, I. V. Nagornova, Yu. V. Rudyak, V. G. Nazarov, L. G. Varepo, “The automating of the quantitative analysis and characterization of the polymer based films surfaces SEM-images”, J. Phys.: Conf. Ser., 1546 (2020), 012027 | DOI | DOI

[74] R. O. Gorbatov, E. E. Malyshev, A. D. Romanov, N. N. Karyakin, “Total knee arthroplasty using virtual prototyping and additive manufacturing”, Modern Technologies in Medicine, 10:3 (2018), 146–154

[75] P. A. Sevostyanov, T. A. Samoilova, M. L. Tikhomirova, “Dry and viscous friction, statistical factors, fluctuation-dissipation theorem and features of their manifestations in relaxation of fibrous materials”, Fibre Chemistry, 51:6 (2020), 449–451 | DOI | DOI

[76] S. B. Bulgarevich, M. V. Boyko, “Effective activation energies of chemical reactions and viscous flow of liquids depending on pressure in tribosystems with boundary and mixed friction”, Journal of Friction and Wear, 38:2 (2017), 132–137 | DOI | DOI

[77] T. D. Ngo, A. Kashani, G. Imbalzano, K. T.Q. Nguyen, D. Hui, “Additive manufacturing (3D-printing): a review of materials, methods, applications and challenges”, Composites Part B: Engineering, 143 (2018), 172–196 | DOI | DOI

[78] J. Lee, T. S. Jang, H. D. Jung, H. Lee, K. H. Cheon, C. Park, H. E. Kim, “Fabrication of poly(lactic acid)/ti composite scaffolds with enhanced mechanical properties and biocompatibility via fused filament fabrication (FFF)-based 3D printing”, Additive Manufacturing, 30 (2019), 100883 | DOI | DOI

[79] F. A. Doronin, M. A. Savelev, I. P. Taranets, Yu. V. Rudyak, G. O. Rytikov, V. G. Nazarov, “Variatsionno-rotatsionnaya anizotropiya kak novyi podkhod k kolichestvennoi otsenke stepeni morfologicheskoi geterogennosti poverkhnosti polimernykh materialov”, Rossiiskii khimicheskii zhurnal, 65:4 (2021), 8–15 | DOI | MR | DOI | MR