Область научных интересов лаборатории -
механика новых материалов, в том числе наноматериалов;
теория процессов деформации и разрушения в наноматериалах.

Руководитель лаборатории - д.ф.-м.н. Илья Анатольевич Овидько
(по данным Web of Science число ссылок на его статьи Cv = 3989; индекс Хирша H = 33)

Сотрудники лаборатории:

Арчаков Иван Юрьевич	к.х.н., старший научный сотрудник	(Cv = 82; H = 5)
Бобылев Сергей Владимирович	д.ф.-м.н., ведущий научный сотрудник	(Cv = 476; H = 12)
Гуткин Михаил Юрьевич	д.ф.-м.н., главный научный сотрудник	(Cv = 2342; H = 25)
Колесникова Анна Львовна	д.ф.-м.н., ведущий научный сотрудник	(Cv = 625; H = 13)
Конаков Ярослав Владимирович	младший научный сотрудник	(Cv = 3; H = 1)
Скиба Николай Васильевич	д.ф.-м.н., ведущий научный сотрудник	(Cv = 486; H = 13)
Шейнерман Александр Григорьевич	д.ф.-м.н., ведущий научный сотрудник	(Cv = 1326; H = 20)

Сотрудники лаборатории выполняют исследования по основному научному направлению ИПМаш РАН
Механика новых материалов, в том числе наноматериалов
(научный руководитель - д.ф.-м.н. И.А. Овидько)

В 2011-2017 годах сотрудники лаборатории принимали/принимают участие в НИР, выполняемых по грантам и заданиям различных фондов и организаций.

Исследовательский проект по теории механических свойств новых керамических нанокомпозитов
(руководитель - И.А. Овидько).
Программа фундаментальных исследований Президиума РАН по нанотехнологиям и наноматериалам.

• Грант РФФИ по теме "Механика пластичности нанокристаллических твердых тел"
  (руководитель - И.А. Овидько).
• Грант Президента РФ для молодых докторов наук. Микромеханика процессов пластической деформации и разрушения, реализуемых посредством трансформаций внутренних границ раздела в наноструктурных твердых телах и нанокомпозитах (2017-2018).
  (руководитель - С.В. Бобылев)
• Грант Президента РФ для молодых кандидатов наук МК-1702.2010.1 "Микромеханика процессов пластической деформации в наномасштабных объектах и нанокристаллических материалах", (2010-2011 гг.)
  (руководитель - С.В. Бобылев)
• Грант РФФИ - 12-01-31350 "Механика процессов пластического деформирования нанопроволок", (2012-2013 гг.)
  (руководитель - С.В. Бобылев)
• Грант Президента РФ МК-5600.2011.1 "Микромеханика повышения трещиностойкости нанокристаллических твердых тел" (2011-2012 гг.)
  (руководитель - Н.В. Скиба)
• Грант РФФИ - 12-02-31642-мол-а "Физические микромеханизмы торможения трещин в деформируемых нанокристаллических материалах" (2012-2013 гг.)
  (руководитель - Н.В. Скиба)
• Грант Комитета по науке и высшей школе Правительства Санкт-Петербурга "Микромеханизмы пластичности нанокристаллических материалов" (2012 г.)
  (руководитель - Н.В. Скиба)
• Грант Президента РФ для молодых докторов наук. Механика взаимодействия процессов разрушения и пластической деформации в нанокристаллических твердых телах (2012-2013 гг.)
  (руководитель - А.Г. Шейнерман)
• Грант Президента РФ для молодых докторов наук. Микромеханика высокой прочности и пластичности нанодвойниковых материалов (2015-2016 гг.)
  (руководитель - А.Г. Шейнерман)
• Грант РФФИ для ведущих молодежных коллективов. Микромеханика процессов пластической деформации и разрушения в нанодвойникованных материалах (2015-2016 гг.)
  (руководитель - А.Г. Шейнерман)
• Грант Правительства Санкт-Петербурга для молодых ученых. Механизмы пластической деформации и трещиностойкости нанокристаллических материалов (2011 г.)
  (руководитель - А.Г. Шейнерман)

Прошли успешные защиты двух докторских диссертаций молодых сотрудников лаборатории, а именно, С.В. Бобылевым в 2013 году и Н.В. Скибой в 2014 году.

С.В. Бобылев:

диссертация "Наномасштабная пластическая деформация и трансформации границ раздела в нанокристаллических твердых телах"

на соискание ученой степени доктора физико-математических наук (2013).

Н.В. Скиба:

диссертация "Взаимодействие мод пластической деформации и их влияние на зарождение и рост трещин в нанокристаллических твердых телах"

на соискание ученой степени доктора физико-математических наук (2014).

Публикации сотрудников лаборатории механики наноматериалов и теории дефектов

1. C.C. Koch, I.A. Ovid'ko, S. Seal and S. Veprek, Structural Nanocrystalline Materials: Fundamentals and Applications (Cambridge University Press, Cambridge, 2007). Перевод: К. Коч, И. Овидько, С. Сил, С. Вепрек, Конструкционные нанокристаллические материалы (Москва: Физматлит, 2012) 448 с.
2. M.Yu. Gutkin and I.A. Ovid'ko, Plastic Deformation in Nanocrystalline Materials (Springer, Berlin, New York, etc., 2004).
3. С.В. Бобылев, И.А. Овидько, Границы зерен и пластическая деформация в наноматериалах /. - СПб.: Изд-во Политехн. ун-та, 2016. - 184 с. (ISBN 978-5-7422-5508-6)
4. И.А. Овидько, А.Г. Шейнерман, Механика нанопроволок и наноструктурных пленок (С.-Петербург, Норд-Экслибрис, 2011), 181 с. I.A. Ovid'ko and A.G. Sheinerman, Mechanics of Nanowires and Nanostructured Films (St.Petersburg: Nord-Exlibris, 2011) (in Russian)
5. И.А. Овидько, Б.Н. Семенов, А.Г. Шейнерман, Механика деформируемых наноматериалов (С.-Петербург, СПбГУ, 2013), 142 с. I.A. Ovid'ko, B.N. Semenov and A.G. Sheinerman, Mechanics of Deformed Nanomaterials (St.Petersburg: St. Petersburg State University, 2013) (in Russian)
6. M.Yu. Gutkin and I.A. Ovid'ko, Physical Mechanics of Deformed Nanostructures. Volume 2: Layered Nanostructures (St.Petersburg: Yanus, 2005) (in Russian)
7. I.A. Ovid'ko and A.G. Sheinerman, Nanomechanics of Quantum Dots and Wires (St.Petersburg: Yanus, 2004) (in Russian)
8. M.Yu. Gutkin and I.A. Ovid'ko, Physical Mechanics of Deformed Nanostructures. Volume 1: Nanocrystalline Materials (St.Petersburg: Yanus, 2003) (in Russian)
9. M.Yu. Gutkin and I.A. Ovid'ko, Defects and Plasticity Mechanisms in Nanostructured and Non-crystalline Materials (St.Petersburg, Yanus, 2001) (in Russian)
10. I.A. Ovid'ko, Defects in Condensed Media: Glasses, Crystals, Quasicrystals, Liquid Crystals, Magnetics, Superfluids (St.Petersburg: Znanie, 1991) (in Russian)

Приглашенные главы в монографиях в 2011-2017 годах:

1. I.A. Ovid'ko, Grain boundaries in graphene. Chapter in book: Nanomaterials Handbook (Taylor & Francis, U.K., 2017), edited by Y.G. Gogotsi.
2. I.A. Ovid'ko, A.G. Sheinerman, Plastic deformation and fracture processes in bulk nanotwinned materials and nanotwinned nanowires. pp- 46-64. Chapter in book: Nanofabrication using Nanomaterials (One Central Press, Manchester, U.K., 2016), edited by J. Ebothe and W. Ahmed.
3. I.A. Ovid'ko. Enhanced ductility and its mechanisms in nanocrystalline metallic materials, In: Nanostructured Metals and Alloys: Processing, Microstructure, Mechanical Properties and Applications. Ed. by S.H. Whang. Oxford/Cambridge/Philadelphia, Woodhead Publ. Ltd, 2011, Chapter 14, p. 430-458.
4. I.A. Ovid'ko and A.G. Sheinerman, Fracture behavior of nanocrystalline ceramics. Chapter 9. In: Mechanical Properties of Nanocrystalline Materials, edited by J.C.M. Li (Pan Stanford Publishing Pte. Ltd., 2011), pp. 245-275.
5. M.Yu. Gutkin. Elastic and plastic deformation in nanocrystalline metals. In: Nanostructured Metals and Alloys: Processing, Microstructure, Mechanical Properties and Applications. Ed. by S.H. Whang. Oxford/Cambridge/Philadelphia Woodhead Publ. Ltd. 2011; Chapter 12: 329-374.

Статьи, опубликованные в 2011-2017 годах в журналах,
индексируемых в Web of Science (Core Collection) и/или Scopus:

1. Bobylev S.V., Ovid'ko I.A., Stress-driven migration, convergence and splitting transformations of grain boundaries in nanomaterials. Acta Mater 124 (2017) 333-342.
2. I.Evazzade, I.P. Lobzenko, E.A. Korznikova, I.A. Ovid'ko, M.R. Roknabadi, and S.V. Dmitriev, Energy transfer in strained graphene assisted by discrete breathers excited by external ac driving. Phys. Rev. B 95, 035423 (2017).
3. Ovid'ko I.A., Sheinerman A.G., Free surface effects on stress-driven grain boundary sliding and migration processes in nanocrystalline materials. Acta Mater 121 (2016) 117-125.
4. Ovid'ko I.A., Sheinerman A.G., Free surface effects on rotational deformation in nanocrystalline materials. J Mater Sci 51, n 13 (2016) 6444-6451.
5. I.A. Ovid'ko, A.G. Sheinerman, Plastic deformation through de-twinning mediated by incoherent twin boundaries in nanotwinned metallic alloys. // Reviews on Advanced Materials Science, Volume 47 (2016) 1-8.
6. Murashkin M.Yu., Medvedev A.E., Kazykhanov V.U., Raab G.I., Ovid.ko I.A., Valiev R.Z., Microstructure, strength, electrical conductivity and heat resistance of an Al-Mg-Zr alloy after ECAP-Conform and cold drawing Reviews on Advanced Materials Science, Volume 47, Issue 1, Pages 16-25 (2016).
7. I.A. Ovid'ko, N.V. Skiba, Formation of paired twins at grain boundaries in nanostructured and coarse-grained materials under plastic deformation. // Reviews on Advanced Materials Science, Volume 47 (2016) 66-73.
8. A.S. Kochnev, I.A. Ovid'ko, B.N. Semenov, Superplasticity of highly disclinated graphene. // Reviews on Advanced Materials Science, Volume 47 (2016) 79-85.
9. I.A. Ovid'ko, A.G. Sheinerman, Transmission of deformation twins across grain boundaries in nanocrystalline and ultrafine-grained materials. // Reviews on Advanced Materials Science, Volume 45, Issue 1-2 (2016) 76-83.
10. I.A. Ovid'ko, N.V. Skiba, A.G. Sheinerman, Nucleation of nanograins through stress-driven migration of grain boundaries in nanomaterials and Gum metals. // Reviews on Advanced Materials Science, Volume 45, Issue 1-2 (2016) 91-96.
11. V.G. Konakov, O.Yu. Kurapova, I.V. Lomakin, I.Yu. Archakov, E.N. Solovyeva and I.A. Ovid'ko, Fabrication of Aluminum-graphene and Metal-ceramic Nanocomposites. A Selective Review. // Reviews on Advanced Materials Science, Volume 44, Issue 4, (2016) 361-369.
12. V.G. Konakov, O.Yu. Kurapova, I.V. Lomakin, I.Yu. Archakov, E.N. Solovyeva and I.A. Ovid'ko, Nanotwinned copper - graphene composite: synthesis and microstructure. // Reviews on Advanced Materials Science, Volume 45, Issue 1/2, (2016) 1-7.
13. Конаков Я.В. Овидько, И.А., Шейнерман, А.Г., Влияние когерентных нановключений на стимулируемую напряжением миграцию малоугловых границ зерен в нанокомпозитах. Физика твердого тела Том 58, Выпуск 9, Страницы 1757-1763 (2016).
14. Кочнев А.С., Морозов Н.Ф., Овидько, И.А., Б.Н. Семенов. Процессы деформации и разрушения в графене с бивакансиями типа 555-777. Доклады академии наук. Том 469, Выпуск 6 (2016) 672-675.
15. Бобылев, С.В., Овидько, И.А., Зарождение деформационных двойников на скользящих зернограничных дислокациях в наноматериалах Физика твердого тела, Том 58, Выпуск 3, Страницы 558-563 (2016).
16. Кочнев А.С., Морозов Н.Ф., Овидько, И.А., Б.Н. Семенов. Процессы деформации и разрушения в графеновых нанолентах с линейными квадруполями дисклинаций. Доклады академии наук. Том 468, Выпуск 3 (2016) 272-275.
17. Бобылев, С.В., Овидько, И.А., Испускание дислокаций из межфазных границ в деформируемых нанокомпозитах Физика твердого тела Том 58, Выпуск 6, Страницы 1135-1141 (2016).
18. Овидько, И.А., Шейнерман, А.Г. Зарождение трещин вблизи свободной поверхности в деформируемых металлических наноматериалах с бимодальной структурой Физика твердого тела Том 58, Выпуск 6, Страницы 1142-1146 (2016).
19. I.A. Ovid'ko, A.G. Sheinerman, N.V. Skiba. Micromechanics of twinning and detwinning processes in nanocrystalline and ultrafine-grained metals. // Materials Physics and Mechanics, 27, 1 (2016) 42-52.
20. A.S. Kochnev, I.A. Ovid'ko. Mechanical characteristics of graphene sheets with 5-5-5-9 defects. // Materials Physics and Mechanics, 27, 1 (2016) 60-67.
21. V.G. Konakov, O.Yu. Kurapova, A.R. Arutyunyan, I.V. Lomakin, E.N. Solovyova, N.N. Novik, I.A. Ovid'ko. Structure and mechanical characteristics of Ni . 1 wt.% Y2O3-92ZrO2 nanocomposites fabricated by powder metallurgy method. // Materials Physics and Mechanics, 27, 1 (2016) 90-97.
22. Бобылев, С.В., Овидько, И.А. Процессы наномасштабного идеального пластического наносдвига в деформируемых нанокристаллических материалах и нанопроволоках. Materials Physics and Mechanics, 27, 2 (2016) 142-170.
23. Бобылев, С.В., Овидько, И.А. О минимальном размере зерен в ультрамелкозернистых материалах и Гам-металлах при интенсивном пластическом деформировании. Materials Physics and Mechanics, 29, 1 (2016) 17-23.
24. Бобылев, С.В., Овидько, И.А. Аккомодация зернограничного скольжения и повыщение трещиностойкости в деформируемых нанокристаллических материалах. Materials Physics and Mechanics, 29, 1 (2016) 43-70.
25. S.V. Bobylev and I.A. Ovid'ko, Anomalous multiplication of lattice dislocations at grain boundaries in nanocrystalline solids. Journal of Physics D: Applied Physics 48, N 3 (2015) 035302.
26. S.V. Bobylev and I.A. Ovid'ko, Stress-driven migration of deformation-distorted grain boundaries in nanomaterials. Acta Materialia 88, N 3 (2015) 260-270.
27. I.A. Ovid'ko and A.G. Sheinerman, Effects of incoherent nanoinclusions on stress-driven migration of low-angle grain boundaries in nanocomposites. // Journal of Materials Science 50, N 12 (2015) 4430-4439.
28. Kochnev, A.S., Ovid'ko, I.A., Giant plasticity of ultranarrow graphene nanoribbons Reviews on Advanced Materials Science, Volume 43, Issue 1/2, Pages 77-82 (2015).
29. I.A. Ovid'ko, A.G. Sheinerman. Mechanical properties of nanotwinned metals: a review. // Reviews on Advanced Materials Science, Vol. 44, N 1 (2016) 1-25.
30. И.С. Ясников, А.Л. Колесникова, А.Е. Романов, Мультидисклинационные конфигурации в пентагональных микрокристаллах и двумерных углеродных структурах // Физика твердого тела Том 58, Вып. 6 (2016) с. 1147-1152.
31. A.L. Kolesnikova, M.Yu. Gutkin, A.V. Proskura, N.F. Morozov, A.E. Romanov, Elastic fields of straight wedge disclinations axially piercing bodies with spherical free surfaces // International Journal of Solids and Structures, Vol. 99 (2016) pp. 82.96.
32. S.A. Krasnitckii, A.M. Smirnov, M.Yu. Gutkin. Misfit stresses in a core-shell nanowire with core in the form of long parallelepiped // Journal of Physics: Conference Series, 2016, Vol. 690, Art. No. 012022 (6 pp.).
33. М.Ю. Гуткин, А.М. Смирнов. Начальные стадии релаксации напряжений несоответствия путем образования призматических дислокационных петель в композитных наноструктурах GaN-Ga₂O₃ // ФТТ, 2016, т. 58, N 8, с. 1558-1567.
34. I.A. Ovid'ko, Mechanics of fracturing in nanoceramics, Phil. Trans. R. Soc. A 373 N 2038 (2015) 20140129.
35. I.A. Ovid'ko, A.G. Sheinerman (2015) Defect-assisted fracture of polycrystalline graphene. Proceedings of 4th International Conference on Materials Engineering for Advanced Technologies (ICMEAT), London, UK, 27-28 June, 2015 (Destech Publ. Inc, 2015), pp. 388-391.
36. A.E. Romanov, A.L. Kolesnikova, T.S. Orlova, I. Hussainova, V.E. Bougrov, R.Z. Valiev (2015) Non-equilibrium grain boundaries with excess energy in graphene. Carbon, 81(1):223-231.
37. I.A. Ovid'ko, A.G. Sheinerman, N.V. Skiba, S.A. Krasnitskiy, A.M. Smirnov (2015) Twin boundary migration and nanocrack generation in ultrafine-grained materials with nanotwinned structure. WSEAS Transactions on Applied and Theoretical Mechanics, 10:204-212.
38. M. Yu. Gutkin, S.A. Krasnitckii, A.M. Smirnov, A.L. Kolesnikova, A.E. Romanov (2015) Dislocation loops in solid and hollow semiconductor and metal nanoheterostructures. Physics of the Solid State, 57(6):1177-1182.
39. M.Yu. Gutkin, A.L. Kolesnikova, S.A. Krasnitckii, L.M. Dorogin, V.S. Serebryakova, A.A. Vikarchuk, A.E. Romanov (2015) Stress Relaxation in Icosahedral Small Particles via Generation of Circular Prismatic Dislocation Loops. Scripta Materialia, 105:10-13.
40. I.S. Yasnikov, A.L. Kolesnikova, A.E. Romanov (2015) Multi-disclination description of pentagonal particles with subsurface layer free of twin boundaries. Philosophical Magazine Letters, 95(9):450-457.
41. H.M. Shodja, C. Enzevaee, M.Yu. Gutkin (2015) Interface effect on the formation of a dipole of screw misfit dislocations in an embedded nanowire with uniform shear eigenstrain field. European Journal of Mechanics - A/Solids, 51(1):154-159.
42. T.S. Argunova, M.Yu. Gutkin, O.P. Kazarova, E.N. Mokhov, S.S. Nagalyuk, J.H. Je (2015) Synchrotron x-ray study on crack prevention in AlN crystals grown on gradually decomposing SiC substrates. Mater. Sci. Forum, 821-823:1011-1014.
43. M.Yu. Gutkin, A.M. Smirnov (2015) Initial stages of misfit stress relaxation in composite nanostructures through generation of rectangular prismatic dislocation loops. Acta Materialia, 88:91-101.
44. E.A. Rzhavtsev, M.Yu. Gutkin (2015) Computer simulation of fragmentation processes in FCC metals under shock compression by 2D dislocation-disclination dynamics. Scripta Materialia, 100:102-105.
45. T.S. Argunova, M.Yu. Gutkin, V.G. Kohn, E.N. Mokhov (2015) Mechanisms of the formation of morphological features of micropipes in bulk crystals of silicon carbide. Physics of the Solid State, 57(4):752-759.
46. M.Yu. Gutkin, E.A. Rzhavtsev (2015) Dynamics of formation of low-angle tilt boundaries in metals and alloys at high loading rates. Physics of the Solid State. 57(12):2447-2457.
47. T.S. Argunova , M.Yu. Gutkin, E.N. Mokhov, O.P. Kazarova, J.-H. Lim, M.P. Shcheglov (2015) Prevention of AlN crystal from cracking on SiC substrates by evaporation of the substrates. Physics of the Solid State. 57(12):2473-2478.
48. V.G. Konakov, O.Yu. Kurapova, N.N. Novik, A.S. Graschenko, A.V. Osipov, I.Yu. Archakov (2015) Approach for electrochemical deposition of copper-graphite films. Materials Physics and Mechanics, 24(1):61-71.
49. S.V. Bobylev, A.G. Sheinerman (2015) Critical stress for dislocation formation in deformed twinned nanowires. Reviews on Advanced Materials Science, 43(1/2):31-37.
50. I.A. Ovid'ko, N.V. Skiba, A.G. Sheinerman (2015) Plastic deformation through detwinning and its effect on electric resistivity in ultrafine-grained metals with nanotwinned structures. Reviews on Advanced Materials Science, 43(1/2):38-44.
51. A.S. Kochnev and I. A. Ovid'ko (2015) Local crystal-to-glass and glass-to-crystal transformations in graphene under tensile deformation. Reviews on Advanced Materials Science, 43(1/2):89-92.
52. N.F. Morozov, I.A. Ovid'ko, N.V. Skiba (2015) Micromechanics of plastic deformation of nanotwinned metals due to twin widening. Doklady Physics, 60(11): 507-510.
53. I.A. Ovid'ko, N.V. Skiba and A.G. Sheinerman (2015) Plastic deformation modes in ultrafine-grained metals with nanotwinned structures. Reviews on Advanced Materials Science, 41(1):93-98.
54. N.F. Morozov, I.A. Ovid'ko, N.V. Skiba (2014) Plastic flow through widening of nanoscale twins in ultrafine-grained metallic materials with nanotwinned structures. Rev. Adv. Mater. Sci., 37(1):29-36.
55. S.V. Bobylev, I.A. Ovid'ko (2014) Nanodisturbance deformation mode in FCC nanowires, micropillars and bulk nanocomposites. Reviews on Advanced Materials Science 37(1/2):90-96.
56. S. Rezazadeh-Kalehbasti, M.Yu. Gutkin, H.M. Shodja (2014) Wedge disclinations in the shell of a core-shell nanowire within the surface/interface elasticity. Mech. Mater., 68(1):45-63.
57. C. Enzevaee, M.Yu. Gutkin, H.M. Shodja. (2014) Surface/interface effects on the formation of misfit dislocation in a core-shell nanowire. Phil. Mag., 94(5):492-519.
58. M.Yu. Gutkin, S.N. Panpurin (2014) Equilibrium ensembles of quantum dots in atomically inhomogeneous pentagonal nanowires. Phys. Solid State, 56(6):1187-1194.
59. M.Yu. Gutkin, A.M. Smirnov (2014) Generation of rectangular prismatic dislocation loops in shells and cores of composite nanoparticles. Phys. Solid State, 56(4):731-738.
60. M.Yu. Gutkin, A.L. Kolesnikova, S.A. Krasnitckii, A.E. Romanov (2014) Misfit dislocation loops in composite core-shell nanoparticles. Phys. Solid State, 56(4):723-730.
61. O.Yu. Kurapova, V.G. Konakov (2014) Phase evolution in zirconia based systems. Rev. Adv. Mater. Sci., 36(2):177-190.
62. V.G. Konakov, I.A. Ovid'ko, O. Yu. Kurapova, N.N. Novik, S.N. Golubev, A.V. Osipov, I.Yu. Archakov (2014) Optimized approach for synthesis of nanotwinned copper with enhanced hardness. Rev. Adv. Mater. Sci., 39(1/2):1-7.
63. I.A. Ovid'ko, A.G. Sheinerman, R.Z. Valiev (2014) Dislocation emission from deformation-distorted grain boundaries in ultrafine-grained materials. Scripta Mater., 76:45-48.
64. A.E. Romanov,L.M. Dorogin, A.L. Kolesnikova, I. Kink, I.S. Yasnikov, A.A. Vikarchuk (2014) A model of whisker crystal growth from a pentagonal small particle. Tech. Phys. Lett., 40(2):174-176.
65. A.L. Kolesnikova, T.S. Orlova, I. Hussainova, A.E. Romanov (2014) Elastic models of defects in two-dimensional crystals. Phys. Solid State, 56(12):2573-2579.
66. I.A. Ovid'ko, A.G. Sheinerman (2014) Nanoscale cracks at deformation twins stopped by grain boundaries in bulk and thin-film materials with nanocrystalline and ultrafine-grained structures. J. Phys. D, 47:015307.
67. I.A. Ovid'ko, A.G. Sheinerman, R.Z. Valiev (2014) Mg segregations at and near deformation-distorted grain boundaries in ultrafine-grained Al-Mg alloys. J. Mater. Sci., 49:6682-6688.
68. I.A. Ovid'ko, A.G. Sheinerman (2014) Grain boundary rotations near crack tips in deformed nanomaterials. Rev. Adv. Mater. Sci., 37(1/2):97-104.
69. Ya.V. Konakov, I. A. Ovid'ko and A.G. Sheinerman (2014) Equilibrium dislocation structures at grain boundaries in subsurface areas of polycrystalline graphene and ultrafine-grained metals. Rev. Adv. Mater. Sci., 37(1/2):83-89.
70. T.S. Argunova, M.Yu. Gutkin, J.H. Je, J.H. Lim, E.N. Mokhov, A.D. Roenkov (2014) Structural transformation of lattice defects in free-spreading growth of bulk SiC crystals. Cryst. Eng. Comm, 16(37):8917-8923.
71. M.Yu. Gutkin, A.L. Kolesnikova, S.A. Krasnitckii, A.E. Romanov, A.G. Shalkovskii (2014) Misfit dislocation loops in hollow core-shell nanoparticles. Scripta Materialia, 83(1):1-4.
72. N.F. Morozov, I.A. Ovid'ko, N.V. Skiba (2013) Influence of nucleation of the chains of nanoscopic grains near the vertexes of cracks on the crack resistance of nanocrystalline ceramics. Doklady Physics, 58 (6): 249-252, doi:10.1134/S1028335813060049
73. N.F. Morozov, I.A. Ovid'ko, N.V. Skiba, A.G. Sheinerman (2013) Influence of nanotwin generation near crack tips on the fracture toughness of nanomaterials. Doklady Physics, 58 (12): 544-547, doi:10.1134/S1028335813120082
74. A.L. Kolesnikova, M.Yu. Gutkin, S.A. Krasnitckii, A.E. Romanov (2013) Circular prismatic dislocation loops in elastic bodies with spherical free surfaces. International Journal of Solids and Structures, 50 (10): 1839-1857, doi:10.1016/j.ijsolstr.2013.02.012
75. M.Yu. Gutkin, S.N. Panpurin (2013) Spontaneous formation and equilibrium distribution of cylindrical quantum dots in atomically inhomogeneous pentagonal nanowires. Journal of Macromolecular Science B, 52 (12): 1756.1769, doi:10.1080/00222348.2013.808929
76. M.Yu. Gutkin, S. Rezazadeh-Kalehbasti, H.M. Shodja (2013) Surface/interface effects on elastic behavior of an edge dislocation in the shell of a core-shell nanowire. European Journal of Mechanics A-Solids, 41: 86-100, doi:10.1016/j.euromechsol.2013.02.008
77. M.Yu. Gutkin, C. Enzevaee, H.M. Shodja (2013) Interface effects on elastic behavior of an edge dislocation in a core-shell nanowire embedded to an infinite matrix. International Journal of Solids and Structures, 50 (7-8): 1177-1186, doi:10.1016/j.ijsolstr.2012.12.008
78. A.G. Sheinerman, M.Yu. Gutkin, T.S. Argunova, E.N. Mokhov, S.N. Nagalyuk, J.H. Je (2013) Contact-free micropipe reactions in silicon carbide. Materials Science Forum (740-742): 597-600, doi:10.4028/www.scientific.net/MSF.740-742.597
79. A.L. Kolesnikova, R.M. Soroka, A.E. Romanov (2013) Defects in the elastic continuum: classification, fields and physical analogies. Materials Physics and Mechanics, 17 (1): 71-91
80. V.G. Konakov, E.N. Solovyeva, I.Yu. Archakov, S.N. Golubevy (2013) Strength of Al2O3-SiC-BN-Si3N4-based ceramics. Materials Physics and Mechanics, 18 (1): 93-100
81. I.A. Ovid'ko (2013) Mechanical properties of graphene. Reviews on Advanced Materials Science, 34 (1): 1-11
82. I.A. Ovid'ko (2013) Highly disclinated graphene. Reviews on Advanced Materials Science, 34 (1): 12-18
83. I.A. Ovid'ko (2013) Enhanced mechanical properties of polymer-matrix nanocomposites reinforced by graphene inclusions: a review. Reviews on Advanced Materials Science, 34 (1): 19-25
84. I.A. Ovid'ko, E.C. Aifantis (2013) Nanocrystals & nanomechanics: mechanisms & models. A selective review. Reviews on Advanced Materials Science, 35 (1/2): 1-24
85. S.V. Bobylev, I.A. Ovid'ko (2013) Stress-driven rotations of high-angle grain boundaries in nanomaterials. Reviews on Advanced Materials Science, 35 (1/2): 25-38
86. I.A. Ovid'ko, A.G. Sheinerman (2013) Kinetics of grain boundary sliding and rotational deformation in nanomaterials. Reviews on Advanced Materials Science, 35 (1/2): 48-58
87. I.A. Ovid'ko, N.V. Skiba (2013) Formation of nanoscopic grains due to dislocation pile-up transformations in deformed ultrafine-grained materials. Reviews on Advanced Materials Science, 35 (1/2): 96-103
88. Ya.V. Konakov, I.A. Ovid'ko, A.G. Sheinerman (2013) Inhomogeneous dislocation structures of disclinated grain boundaries in graphene and ultrafine-grained metals. Reviews on Advanced Materials Science, 35 (1/2): 104.109
89. V.G. Konakov, E.N. Solovyeva, I.Yu. Archakov, S.N. Golubev (2013) The effect of phase transitions in Al₂O₃-SiC-BN zirconia doped system on the mechanical properties of ceramics. Reviews on Advanced Materials Science, 35 (1/2): 86-95
90. A.V. Lobanova, A.L. Kolesnikova, A.E. Romanov, S.Yu. Karpov, M.E. Rudinsky, E.V. Yakovlev (2013) Mechanism of stress relaxation in (0001) InGaN/GaN via formation of V-shaped dislocation half-loops. Applied Physics Letters, 103 (15): 152106
91. I.A. Ovid'ko, A.G. Sheinerman (2013) Cracks at disclinated grain boundaries in graphene. Journal of Physics D, 46 (34): 345305, doi:10.1088/0022-3727/46/34/345305
92. S.V. Bobylev, I.A. Ovid'ko (2012) Grain boundary rotations in solids. Physical Review Letters, 109 (17): 175501(1-5), doi:10.1103/PhysRevLett.109.175501
93. ,b>I.A. Ovid'ko (2012) Nanoscale multiplane shear and twin deformation in nanowires and nanocrystalline solids. Applied Physics Letters, 99 (6): 061907(1-3), doi:10.1063/1.3620934
94. S.V. Bobylev, I.A. Ovid'ko (2012) Nanodisturbances and nanoscale deformation twins in fcc nanowires. Physical Review B., 83 (5): 054111(1-13), doi:10.1103/PhysRevB.83.054111
95. S.V. Bobylev, N.F. Morozov, I.A. Ovid'ko (2012) Cooperative grain boundary sliding and nanograin nucleation process in nanocrystalline, ultrafine-grained, and polycrystalline solids. Physical Review B., 84 (9): 094103(1-10), doi:10.1103/PhysRevB.84.094103
96. S.V. Bobylev, T. Ishizaki, S. Kuramoto, I.A. Ovid'ko (2012) Formation of nanocrystals due to giant-fault deformation in Gum Metals. Scripta Materialia , 65 (8): 668.671, doi:10.1016/j.scriptamat.2011.07.004
97. I.A. Ovid'ko, A.G. Sheinerman (2011) Micromechanisms for improved fracture toughness in nanoceramics. Reviews on Advanced Materials Science, 29 (2): 105-125
98. N.F. Morozov, I.A. Ovid'ko, N.V. Skiba (2011) Stress-driven formation of nanograin chains in nanocrystalline and ultrafine-grained materials. Reviews on Advanced Materials Science, 29 (2): 180-186
99. I.A. Ovid'ko, A.G. Sheinerman (2011) Deformation twinning through nanoscale ideal shears in nano- and polycrystalline materials at ultra high stresses. Reviews on Advanced Materials Science, 27 (2): 189.194
100. I.A. Ovid'ko, A.G. Shein (2011) Nucleation of misfit dislocations by nanoscale ideal shear in surface nanowires and nanoislands (quantum dots). Reviews on Advanced Materials Science, 27 (1): 83.89
101. I.A. Ovid'ko Crack Generation in Nanomaterials at High-Strain-Rate and Quasistatic Regimes of Deformation. Materials Physics and Mechanics: 76-101
102. I.A. Ovid'ko, A.G. Sheinerman, E.C. Aifantis (2011) Mechanics of Crack Growth Processes in Nanoceramics. Materials Physics and Mechanics, 12 (1): 1-29
103. I.A. Ovid'ko, A.G. Sheinerman (2011) Effect of Hydrogen on Strength of Nanoceramics. Materials Physics and Mechanics, 11 (1): 76-93
104. V.G. Konakov, S.N. Golubev, E.N. Solovyeva, I.Yu. Archakov, N.V. Borisova, A.V. Shorokhov (2011) Correlation between the Precursor Dispersity and Mechanical Strength of Solid Electrolytes Based on Ce₂O₃-ZrO₂ System. Materials Physics and Mechanics, 11 (2): 183-189
105. V.G. Konakov, S.N. Golubev, E.N. Solovyeva, I.Yu. Archakov, N.V. Borisova, A.V. Shorokhov (2011) Agglomerate Size in Precursors and Mechanical Strength of Solid Elestrolytes Based on Y₂O₃-ZrO₂ System. Materials Physics and Mechanics, 11 (1): 68-75
106. I.A. Ovid'ko, N.V. Skiba (2011) Generation of New Nanoscopic Grains near Crack Tips in Deformed Nanocrystalline Materials. Materials Physics and Mechanics, 11 (2): 105-117
107. S.S. Moeini-Ardakani, M.Yu. Gutkin, H.M. Shodja (2011) Elastic behavior of an edge dislocation inside the wall of a nanotube. Scripta Materialia, 64 (8): 709-712, doi:10.1016/j.scriptamat.2010.12.022
108. M.Yu. Gutkin, K.V. Kuzmin, A.G. Sheinerman (2011) Misfit stresses and relaxation mechanisms in a nanowire containing a coaxial cylindrical inclusion of finite length. Physica Status Solidi B., 248 (7): 1651-1657, doi:10.1002/pssb.201046452
109. H.M. Shodja, M.Yu. Gutkin, S.S. Moeini-Ardakani
(2011) Effect of surface stresses on elastic behavior of a screw dislocation inside the wall of a nanotube. Physica Status Solidi B., 248 (6): 1437-1441, doi:10.1002/pssb.201046417
110. T.S. Argunova, M.Yu. Gutkin, J.H. Je, E.N. Mokhov, S.S. Nagalyuk, Y. Hwu (2011) SR phase contrast imaging to address the evolution of defects during SiC growth. Physica Status Solidi A., 208 (4): 819-824, doi:10.1002/pssa.201026341
111. N.A. Bert, A.L. Kolesnikova, I.K. Korolev, A.E. Romanov, A.B. Freidin, V.V. Chaldyshev, E.C. Aifantis (2011) Elastic fields and physical properties of surface quantum dots. Physics of the Solid State, 53 (10): 2091-2102, doi:10.1134/S1063783411100052
112. I.A. Ovid'ko (2012) Nanoscale amorphization as special deformation mode in nanowires. Scripta Materialia, 66 (6): 402-405, doi:10.1016/j.scriptamat.2011.12.001
113. I.A. Ovid'ko, A.G. Sheinerman (2012) Nanoscale rotational deformation near crack tips in nanocrystalline solids. Journal of Physics D., 45 (33): 335301(1-8), doi:10.1088/0022-3727/45/33/335301
114. I.A. Ovid'ko, N.V. Skiba (2012) Enhanced dislocation emission from grain boundaries in nanocrystalline materials. Scripta Materialia, 67 (1): 13-16, doi:10.1016/j.scriptamat.2012.03.007
115. I.A. Ovid'ko, A.G. Sheinerman (2012) Generation and growth of nanocracks near blunt cracks in nanocrystalline solids. European Journal of Mechanics A-Solids, 33: 39-47, doi:10.1016/j.euromechsol.2011.11.001
116. I.A. Ovid'ko (2012) Review on grain boundaries in graphene. Curved poly- and nanocrystalline graphene structures as new carbon allotropes. Reviews on Advanced Materials Science, 30 (3): 201-224
117. I.A. Ovid.ko, T.G. Langdon (2012) Enhanced ductility of nanocrystalline and ultrafine-grained metals. Reviews on Advanced Materials Science, 30 (2): 103-111
118. I.A. Ovid'ko (2012) How to fabricate new carbon nanostructures through grain boundary engineering in grapheme. Reviews on Advanced Materials Science, 32 (1): 1-6
119. S.V. Bobylev, N.F. Morozov, I.A. Ovid'ko, B.N. Semenov, A.G. Sheinerman (2012) Misfit dislocation configurations at interphase boundaries between misoriented crystals in nanoscale film-substrate systems. Reviews on Advanced Materials Science, 32 (1): 24-33
120. V.G. Konakov, A.V. Shorokhov, N.V. Borisova, S.N. Golubev, E.N. Solovyeva, V.M. Ushakov (2012) The effect of nanosize Y₂O₃-ZrO₂, Ce₂O₃-ZrO2, and Ce₂O₃-Y₂O₃-ZrO precursor dispersity on the conductivity and sensor properties of final ceramics. Reviews on Advanced Materials Science, 32 (1): 34-43
121. I.A. Ovid'ko, A.G. Sheinerman (2012) Nanoscale amorphization near crack tips in deformed nanocrystalline and ultrafine-grained materials. Reviews on Advanced Materials Science, 32 (1): 61-67
122. N.F. Morozov, I.A. Ovid'ko, A.G. Sheinerman, N.V. Skiba (2012) Formation of deformation twins through ideal nanoshear events near crack tips in deformed nanocrystalline materials. Reviews on Advanced Materials Science, 32 (1): 75-81
123. N.K. Dynkin, M.Yu. Gutkin (2012) Migration of grain boundaries in free-standing nanocrystalline thin films. Scripta Materialia, 66 (2): 73-76, doi:10.1016/j.scriptamat.2011.09.043
124. M.Yu. Gutkin, N.K. Dynkin (2012) Dislocation-disclination models of grain boundary migration in ultra-thin nanocrystalline films. Physics of the Solid State, 54 (4): 798-807, doi:10.1134/S1063783412040105
125. H.M. Shodja, H. Ahmadzadeh-Bakhshayesh, M.Yu. Gutkin (2012) Size-dependent interaction of an edge dislocation with an elliptical nano-inhomogeneity incorporating interface effects. International Journal of Solids and Structures, 49 (5): 759-770, doi:10.1016/j.ijsolstr.2011.11.013
126. H. Ahmadzadeh-Bakhshayesh, M.Yu. Gutkin, H.M. Shodja (2012) Surface/interface effects on elastic behavior of a screw dislocation in an eccentric core-shell nanowire. International Journal of Solids and Structures, 49 (13): 1665-1675, doi:10.1016/j.ijsolstr.2012.03.020
127. M.Yu. Gutkin (2012) Misfit stress relaxation in composite nanoparticles. International Journal of Engineering Science, 61 (SI): 59-74, doi:10.1016/j.ijengsci.2012.06.010
128. M.Yu. Gutkin, A.G. Sheinerman, V.G. Kohn, T.S. Argunova, M.A. Smirnov, J.H. Je (2012) Contact-free reactions between micropipes in bulk SiC growth. Physica Status Solidi A., 209 (8): 1432-1437, doi:10.1002/pssa.201127682
129. A.E. Romanov, A.A. Vikarchuk, A.L. Kolesnikova, L.M. Dorogin, I. Kink, E.C. Aifantis (2012) Structural transformations in nanorods and nanoparticles triggered by disclinations. Journal of Material Research, 27 (3): 545-551, doi:10.1557/jmr.2011.372
130. A.V. Proskura, A.B. Freidin, A.L. Kolesnikova, N.F. Morozov, A.E. Romanov (2012) Identification of defects in a solid body on the base of surface displacements. Materials Physics and Mechanics, 15 (1): 9-25
131. V.G. Konakov, S.N. Golubev, E.N. Solovyeva, I.Yu. Archakov, N.V. Borisova, A.V. Shorokhov (2012) Agglomerate Size in Precursors and Mechanical Strength of Solid Electrolytes Based on Y₂O₃-ZrO₂, Ce₂O₃-ZrO₂ and Ce₂O₃-Y₂O₃-ZrO₂ Systems. Materials Physics and Mechanics, 14 (1): 1-10
132. S.V. Bobylev, D.A. Druzhinin, I.A. Ovid'ko (2012) Plastic Deformation in Nanowires via Collective Formation of Nanodisturbances. Materials Physics and Mechanics, 14 (1): 47-56
133. I.A. Ovid'ko, N.V. Skiba (2012) Competition between nanoscale plastic deformation and fracture processes near triple junctions of grain boundaries in nanoceramics. Materials Physics and Mechanics, 142: 101-109
134. I.A. Ovid'ko, A.G. Sheinerman, E.C. Aifantis (2011) Effect of cooperative grain boundary sliding and migration on crack growth in nanocrystalline solids. Acta Materialia, 59 (12): 5023.5031, doi:10.1016/j.actamat.2011.04.056
135. I.A. Ovid'ko, A.G. Sheinerman (2011) Nanoscale rotational deformation in solids at high stresses. Applied Physics Letters, 98 (18): 181909(1-3), doi:10.1063/1.3587637
136. I.A. Ovid.ko, A.G. Sheinerman, N.V. Skiba (2011) Elongated nanoscale voids at grain boundaries in nanocrystalline materials. Acta Materialia, 59 (2): 678.685, doi:10.1016/j.actamat.2010.10.005