ТРИБОЛОГИЧЕСКИЕ МОДЕЛИРОВАНИЯ И ПРИМЕНЕНИЯ МЕТАЛЛОМАТРИЧНЫХ КОМПОЗИЦИОННЫХ МАТЕРИАЛОВ

1.

биомедицинских,

Якубов С.Х., Норқулов Э.О. Критический обзор по металломатричных

нанокомпозитов в трибологии//“Samo qalqonlari” научно-информационный

журнал, 11 (3) 2024. - С. 351-360.

2.

Якубов С.Х., Норкулов Э.О. Критический обзор по композиционных

материалов

с

металлической

матрицей//Проблемы

эксплуатации

авиационного оборудования и путы их решения. Перспективы развитие:

Материалы Республиканского научно-теоретической конференции. –

Карши: ИВА Республики Узбекистан, 2024. – С. 64-71.

3.

Якубов С.Х., Норкулов Э.О., Холмуродов Д.С. Разработки технологии

ультрадисперсных порошков на основе тугоплавких металлов // Методы и перспективы инновационного преподавания общетехнических дисциплин:

Материалы Республиканского научно-теоретической конференции. –

Карши: Институт военной авиации Республики Узбекистан, 2024. - С. 47-52.

4. El-Ghazaly A, Anis G, Salem H G. Effect of graphene addition on the mechanical

and tribological behavior of nanostructured AA2124 self-lubricating metal matrix

composite. Compos Part A Appl Sci Manuf 95: 325–336 (2017).

5. Futami T, Ohira M, Muto H, Sakai M. Contact/scratchinduced surface deformation

and damage of copper–graphite particulate composites. Carbon 47(11): 2742–2751

(2009).

6. Hou K H, Ger M D, Wang L M, Ke S T. The wear behaviour of electro-codeposited

Ni–SiC composites. Wear 253(9–10): 994–1003 (2002).

7. Kumar V, Li L, Gui H L, Wang X G, Huang Q X, Li Q Y, Mokdad F, Chen D L, Li

D Y. Tribological properties of AZ31 alloy pre-deformed at low and high strain rates

via the work function. Wear 414–415: 126–135 (2018).

8. Lee C, Li Q Y, Kalb W, Liu X Z, Berger H, Carpick R W, Hone J. Frictional

characteristics of atomically thin sheets.Science 328(5974): 76–80 (2010).

9. Mandal A, Tiwari J K, AlMangour B, Sathish N, Kumar S, Kamaraj M, Ashiq M,

Srivastava A K. Tribological behavior of graphene-reinforced 316L stainless-steel

composite prepared via selective laser melting. Tribol Int 151: 106525 (2020).

10. Nian J Y, Si Y F, Guo Z G. Advances in atomic-scale tribological mechanisms of

solid interfaces. Tribol Int 94:1–13 (2016).

11. Pan S H, Zhang Z N. Fundamental theories and basic principles of triboelectric

effect: A review. Friction 7(1):2–17 (2019).

12. Pan S H, Saso T, Yu N, Sokoluk M, Yao G C, Umehara N, Li X C. New study on

tribological performance of AA7075- TiB2 nanocomposites. Tribol Int 152: 106565

(2020).

13. Reguzzoni M, Fasolino A, Molinari E, Righi M C. Potential energy surface for

graphene on graphene: Ab initio derivation, analytical description, and microscopic

interpretation. Phys Rev B 86(24): 245434 (2012).14. Righi M C, Zilibotti G, Corni S, Ferrario M, Bertoni C M. First-principle molecular

dynamics of sliding diamond surfaces: Tribochemical reactions with water and

loadeffects. J Low Temp Phys 185(1): 174–182 (2016).

15. Wang K L, Zhou H, Zhang K F, Liu X G, Feng X G, Zhang Y S, Chen G, Zheng

Y G. Effects of Ti interlayer on adhesion property of DLC films: A first principle

study.Diam Relat Mater 111: 108188 (2021).

16. Wei B Y, Kong N, Zhang J, Li H B, Hong Z J, Zhu H T, Zhuang Y, Wang B. A

molecular dynamics study on the tribological behavior of molybdenum disulfide with

grain boundary defects during scratching processes. Friction 9(5):1198–1212 (2021).

17. Zhang X, Xu Y X, Wang M C, Liu E Z, Zhao N Q, Shi C S, Lin D, Zhu F L, He C

N. A powder-metallurgy-based strategy toward three-dimensional graphene-like

network for reinforcing copper matrix composites. Nat Commun 11(1): 2775 (2020).

18. Zhang Z N, Pan S H, Yin N, Shen B, Song J. Multiscale analysis of friction behavior

at fretting interfaces. Friction 9(1): 119–131 (2021).

19. Zhang Z N, Yin N, Wu Z S, Pan S H, Wang D A. Research methods of contact

electrification: Theoretical simulation and experiment. Nano Energy 79: 105501

(2020).