Mechanical and tribological properties of nanocomposites incorporated with two-dimensional materials

Zhengjia JI; Lin ZHANG; Guoxin XIE; Wenhu XU; Dan Guo; Jianbin LUO; Braham PRAKASH

doi:10.1007/s40544-020-0401-4

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Review Article | Open Access

Mechanical and tribological properties of nanocomposites incorporated with two-dimensional materials

Zhengjia JI^{¹^,²}, Lin ZHANG^¹, Guoxin XIE^¹(

), Wenhu XU^³, Dan Guo^¹, Jianbin LUO^¹(

), Braham PRAKASH^¹

1 State Key Laboratory of Tribology, Department of Mechanical Engineering, Tsinghua University, Beijing 100084, China

2 College of Mechanical Engineering, Qinghai University, Xi’ning 810016, China

3 Key Laboratory of Tribology, School of Mechatronics Engineering, Nanchang University, Nanchang 330031, China

Show Author Information

Abstract

In recent years, attempts to improve the mechanical properties of composites have increased remarkably owing to the inadequate utilization of matrices in demanding technological systems where efficiency, durability, and environmental compatibility are the key requirements. The search for novel materials that can potentially have enhanced mechanical properties continues. Recent studies have demonstrated that two-dimensional (2D) nanomaterials can act as excellent reinforcements because they possess high modulus of elasticity, high strength, and ultralow friction. By incorporating 2D nanomaterials in a composite, 2D nanomaterial-based composites (2DNBCs) have been developed. In view of this, a critical review of recent mechanical and tribological studies based on 2DNBCs has been undertaken. Matrices such as polymers, ceramics, and metals, as well as most of the representative 2D nanomaterial reinforcements such as graphene, boron nitride (BN), molybdenum disulfide (MoS₂), and transition metal carbides and nitrides (MXenes) have been included in this review. Their preparation strategies, intrinsic mechanical properties, friction and lubrication performances, strengthening mechanisms, influencing factors, and potential applications have been comprehensively discussed. A brief summary and prospects are given in the final part, which would be useful in designing and fabricating advanced 2D nanocomposites in the future.

Keywords

friction wear lubrication two-dimensional (2D) nanomaterials composites mechanical property

References

[1]

S Stankovich, D A Dikin, G H B Dommett, K M Kohlhaas, E J Zimney, E A Stach, R D Piner, S B T Nguyen, R S Ruoff. Graphene-based composite materials. Nature 442(7100): 282-286 (2006)

Google Scholar

[2]

T Ramanathan, A A Abdala, S Stankovich, D A Dikin, M Herrera-Alonso, R D Piner, D H Adamson, H C Schniepp, X Chen, R S Ruoff, et al. Functionalized graphene sheets for polymer nanocomposites. Nat Nanotechnol 3: 327-331 (2008)

Google Scholar

[3]

X Huang, X Y Qi, F Boey, H Zhang. Graphene-based composites. Chem Soc Rev 41(2): 666-686 (2012)

Google Scholar

[4]

S Kim, H T Wang, Y M Lee. 2D nanosheets and their composite membranes for water, gas, and ion separation. Angew Chem Int Ed Engl 58(49): 17512-17527 (2019)

Google Scholar

[5]

X Li, M Sun, C X Shan, Q Chen, X L Wei. Mechanical properties of 2D materials studied by in situ microscopy techniques. Adv Mater Interfaces 5(5): 1701246 (2018)

Google Scholar

[6]

Z Baig, O Mamat, M Mustapha. Recent progress on the dispersion and the strengthening effect of carbon nanotubes and graphene-reinforced metal nanocomposites: A review. Crit Rev Solid State Mater Sci 43(1): 1-46 (2018)

Google Scholar

[7]

C Lee, X D Wei, J W Kysar, J Hone. Measurement of the elastic properties and intrinsic strength of monolayer graphene. Science 321(5887): 385-388 (2008)

Google Scholar

[8]

W Wang, G X Xie, J B Luo. Black phosphorus as a new lubricant. Friction 6(1): 116-142 (2018)

Google Scholar

[9]

M Naguib, M Kurtoglu, V Presser, J Lu, J J Niu, M Heon, L Hultman, Y Gogotsi, M W Barsoum. Two-dimensional nanocrystals produced by exfoliation of Ti₃AlC₂. Adv Mater 23(37): 4248-4253 (2011)

Google Scholar

[10]

J Halim, S Kota, M R Lukatskaya, M Naguib, M Q Zhao, E J Moon, J Pitock, J Nanda, S J May, Y Gogotsi, et al. Synthesis and characterization of 2D molybdenum carbide (MXene). Adv Funct Mater 26(18): 3118- 3127 (2016)

Google Scholar

[11]

V M Hong Ng, H Huang, K Zhou, P S Lee, W X Que, J Z Xu, L B Kong. Recent progress in layered transition metal carbides and/or nitrides (MXenes) and their composites: Synthesis and applications. J Mater Chem A 5(7): 3039-3068 (2017)

Google Scholar

[12]

W Y Dai, F Shao, J Szczerbiński, R McCaffrey, R Zenobi, Y H Jin, A D Schlüter, W Zhang. Synthesis of a two-dimensional covalent organic monolayer through dynamic imine chemistry at the air/water interface. Angew Chem Int Ed Engl 55(1): 213-217 (2016)

Google Scholar

[13]

L C Liu, M Zhou, L Jin, L C Li, Y T Mo, G S Su, X Li, H W Zhu, Y Tian. Recent advances in friction and lubrication of graphene and other 2D materials: Mechanisms and applications. Friction 7(3): 199-216 (2019)

Google Scholar

[14]

Z D Sha, Q X Pei, Z W Ding, J W Jiang, Y W Zhang. Mechanical properties and fracture behavior of single-layer phosphorene at finite temperatures. J Phys D: Appl Phys 48(39): 395303 (2015)

Google Scholar

[15]

C J Shuai, H Sun, C D Gao, P Feng, W Guo, Y Yang, M C Zhao, S Yang, F L Yuan, S P Peng. Mechanical reinforcement of bioceramics scaffolds via fracture energy dissipation induced by sliding action of MoS₂ nanoplatelets. J Mech Behav Biomed Mater 75: 423- 433 (2017)

Google Scholar

[16]

S Bertolazzi, J Brivio, A Kis. Stretching and breaking of ultrathin MoS₂. ACS Nano 5(12): 9703-9709 (2011)

Google Scholar

[17]

C Y Zhi, Y Bando, C C Tang, H Kuwahara, D Golberg. Large-scale fabrication of boron nitride nanosheets and their utilization in polymeric composites with improved thermal and mechanical properties. Adv Mater 21(28): 2889-2893 (2009)

Google Scholar

[18]

J W Jiang, H S Park. Mechanical properties of single-layer black phosphorus. J Phys D: Appl Phys 47(38): 385304 (2014)

Google Scholar

[19]

J B Pang, R G Mendes, A Bachmatiuk, L Zhao, H Q Ta, T Gemming, H Liu, Z F Liu, M H Rummeli. Applications of 2D MXenes in energy conversion and storage systems. Chem Soc Rev 48(1): 72-133 (2019)

Google Scholar

[20]

C Hermosa, B R Horrocks, J I Martínez, F Liscio, J Gómez-Herrero, F Zamora. Mechanical and optical properties of ultralarge flakes of a metal-organic framework with molecular thickness. Chem Sci 6(4): 2553-2558 (2015)

Google Scholar

[21]

D Li, R B Kaner. Graphene-based materials. Science 320(5880): 1170-1171 (2008)

Google Scholar

[22]

H Kim, A A Abdala, C W Macosko. Graphene/polymer nanocomposites. Macromolecules 43(16): 6515-6530 (2010)

Google Scholar

[23]

S F Bartolucci, J Paras, M A Rafiee, J Rafiee, S Lee, D Kapoor, N Koratkar. Graphene-aluminum nanocomposites. Mater Sci Eng: A 528(27): 7933-7937 (2011)

Google Scholar

[24]

D G Papageorgiou, I A Kinloch, R J Young. Mechanical properties of graphene and graphene-based nanocomposites. Prog Mater Sci 90: 75-127 (2017)

Google Scholar

[25]

B W Chieng, N A Ibrahim, W M Z W Yunus, M Z Hussein, V S Giita Silverajah. Graphene nanoplatelets as novel reinforcement filler in poly(lactic acid)/epoxidized palm oil green nanocomposites: Mechanical properties. Int J Mol Sci 13(9): 10920-10934 (2012)

Google Scholar

[26]

M El Achaby, F E Arrakhiz, S Vaudreuil, A El Kacem Qaiss, M Bousmina, O Fassi-Fehri. Mechanical, thermal, and rheological properties of graphene-based polypropylene nanocomposites prepared by melt mixing. Polym Compos 33(5): 733-744 (2012)

Google Scholar

[27]

Y Ni, L Chen, K Teng, J Shi, X M Qian, Z W Xu, X Tian, C S Hu, M J Ma. Superior mechanical properties of epoxy composites reinforced by 3D interconnected graphene skeleton. ACS Appl Mater Interfaces 7(21): 11583-11591 (2015)

Google Scholar

[28]

B Lee, D Lee, J H Lee, H J Ryu, S H Hong. Enhancement of toughness and wear resistance in boron nitride nanoplatelet (BNNP) reinforced Si₃N₄ nanocomposites. Sci Rep 6(1): 27609 (2016)

Google Scholar

[29]

H Porwal, R Saggar, P Tatarko, S Grasso, T Saunders, I Dlouhý, M J Reece. Effect of lateral size of graphene nano-sheets on the mechanical properties and machinability of alumina nano-composites. Ceram Int 42(6): 7533- 7542 (2016)

Google Scholar

[30]

B Lee, M Y Koo, S H Jin, K T Kim, S H Hong. Simultaneous strengthening and toughening of reduced graphene oxide/alumina composites fabricated by molecular-level mixing process. Carbon 78: 212-219 (2014)

Google Scholar

[31]

J Y Sun, Y B Chen, M K Priydarshi, Z Chen, A Bachmatiuk, Z Y Zou, Z L Chen, X J Song, Y F Gao, M H Rümmeli, et al. Direct chemical vapor deposition-derived graphene glasses targeting wide ranged applications. Nano Lett 15(9): 5846-5854 (2015)

Google Scholar

[32]

X J Wang, M Y Lu, L Qiu, H Huang, D Li, H T Wang, Y B Cheng. Graphene/titanium carbide composites prepared by sol-gel infiltration and spark plasma sintering. Ceram Int 42(1): 122-131 (2016)

Google Scholar

[33]

P Colombo, G Mera, R Riedel, G D Sorarù. Polymer-derived ceramics: 40 years of research and innovation in advanced ceramics. J Am Ceram Soc 93(7): 1805- 1837 (2010)

Google Scholar

[34]

Y L Xiao, P P Yao, K Y Fan, H B Zhou, M W Deng, Z X Jin. Powder metallurgy processed metal-matrix friction materials for space applications. Friction 6(2): 219-229 (2018)

Google Scholar

[35]

H Z Ye, X Y Liu, H P Hong. Fabrication of metal matrix composites by metal injection molding—A review. J Mater Process Technol 200(1-3): 12-24 (2008)

Google Scholar

[36]

Y Song, G Y He, Y G Wang, Y Chen. Tribological behavior of boron nitride nanoplatelet reinforced Ni₃Al intermetallic matrix composite fabricated by selective laser melting. Mater Design 165: 107579 (2019)

Google Scholar

[37]

J Hwang, T Yoon, S H Jin, J Lee, T S Kim, S H Hong, S Jeon. Enhanced mechanical properties of graphene/ copper nanocomposites using a molecular-level mixing process. Adv Mater 25(46): 6724-6729 (2013)

Google Scholar

[38]

A Naseer, F Ahmad, M Aslam, B H Guan, W S W Harun, N Muhamad, M R Raza, R M German. A review of processing techniques for graphene-reinforced metal matrix composites. Mater Manuf Processes 34(9): 957- 985 (2019)

Google Scholar

[39]

H Zhang, L B Wang, A G Zhou, C L Shen, Y H Dai, F F Liu, J F Chen, P Li, Q K Hu. Effects of 2-D transition metal carbide Ti₂CT_x on properties of epoxy composites. RSC Adv 6(90): 87341-87352 (2016)

Google Scholar

[40]

A Sorrentino, C Altavilla, M Merola, A Senatore, P Ciambelli, S Iannace. Nanosheets of MoS₂-oleylamine as hybrid filler for self-lubricating polymer composites: Thermal, tribological, and mechanical properties. Polym Compos 36(6): 1124-1134 (2015)

Google Scholar

[41]

Q Xiao, W H Han, R Yang, Y You, R B Wei, X B Liu. Mechanical, dielectric, and thermal properties of polyarylene ether nitrile and boron nitride nanosheets composites. Polym Compos 39(S3): E1598-E1605 (2018)

Google Scholar

[42]

W Dai, J H Yu, Y Wang, Y Z Song, H Bai, K Nishimura, H W Liao, N Jiang. Enhanced thermal and mechanical properties of polyimide/graphene composites. Macromol Res 22(9): 983-989 (2014)

Google Scholar

[43]

D G Papageorgiou, M F Liu, Z L Li, C Vallés, R J Young, I A Kinloch. Hybrid poly(ether ether ketone) composites reinforced with a combination of carbon fibres and graphene nanoplatelets. Compos Sci Technol 175: 60- 68 (2019)

Google Scholar

[44]

Z Cao, X D Wang, J L Li, Y Wu, H P Zhang, J Q Guo, S Q Wang. Reinforcement with graphene nanoflakes in titanium matrix composites. J Alloys Compd 696: 498- 502 (2017)

Google Scholar

[45]

F Y Chen, J M Ying, Y F Wang, S Y Du, Z P Liu, Q Huang. Effects of graphene content on the microstructure and properties of copper matrix composites. Carbon 96: 836-842 (2016)

Google Scholar

[46]

S J Yan, S L Dai, X Y Zhang, C Yang, Q H Hong, J Z Chen, Z M Lin. Investigating aluminum alloy reinforced by graphene nanoflakes. Mater Sci Eng: A 612: 440-444 (2014)

Google Scholar

[47]

L C Tang, Y J Wan, D Yan, Y B Pei, L Zhao, Y B Li, L B Wu, J X Jiang, G Q Lai. The effect of graphene dispersion on the mechanical properties of graphene/ epoxy composites. Carbon 60: 16-27 (2013)

Google Scholar

[48]

Y Wang, Z X Shi, J Yin. Boron nitridenanosheets: Large-scale exfoliation in methanesulfonic acid and their composites with polybenzimidazole. J Mater Chem 21(30): 11371-11377 (2011)

Google Scholar

[49]

G S Shao, P Liu, K Zhang, W Li, X H Chen, F C Ma. Mechanical properties of graphene nanoplates reinforced copper matrix composites prepared by electrostatic self-assembly and spark plasma sintering. Mater Sci Eng: A 739: 329-334 (2019)

Google Scholar

[50]

A Kumar, S M Zo, J H Kim, S C Kim, S S Han. Enhanced physical, mechanical, and cytocompatibility behavior of polyelectrolyte complex hydrogels by reinforcing halloysite nanotubes and graphene oxide. Compos Sci Technol 175: 35-45 (2019)

Google Scholar

[51]

Y Wang, Z X Shi, J H Fang, H J Xu, X D Ma, J Yin. Direct exfoliation of graphene in methanesulfonic acid and facile synthesis of graphene/polybenzimidazole nanocomposites. J Mater Chem 21(2): 505-512 (2011)

Google Scholar

[52]

X M Feng, X Wang, W Y Xing, K Q Zhou, L Song, Y Hu. Liquid-exfoliated MoS₂ by chitosan and enhanced mechanical and thermal properties of chitosan/MoS₂ composites. Compos Sci Technol 93: 76-82 (2014)

Google Scholar

[53]

G P Tandon, G J Weng. The effect of aspect ratio of inclusions on the elastic properties of unidirectionally aligned composites. Polym Compos 5(4): 327-333 (1984)

Google Scholar

[54]

J C H Affdl, J Kardos. The Halpin-Tsai equations: A review. Polym Eng Sci 16(5): 344-352 (1976)

Google Scholar

[55]

X Zhao, Q H Zhang, D J Chen, P Lu. Enhanced mechanical properties of graphene-based Poly(vinyl alcohol) composites. Macromolecules 43(5): 2357- 2363 (2010)

Google Scholar

[56]

P K Sandhya, M S Sreekala, M Padmanabhan, K Jesitha, S Thomas. Effect of starch reduced graphene oxide on thermal and mechanical properties of phenol formaldehyde resin nanocomposites. Compos Part B: Eng 167: 83-92 (2019)

Google Scholar

[57]

K N Spanos, N K Anifantis. Mechanical characterization of hexagonal boron nitride nanocomposites: A multiscale finite element prediction. J Compos Mater 52(16): 2229- 2241 (2017)

Google Scholar

[58]

Z X Guo, L B Song, G B Chai, Z G Li, Y C Li, Z H Wang. Multiscale finite element analyses on mechanical properties of graphene-reinforced composites. Mech Adv Mater Struc 26(20): 1735-1742 (2018)

Google Scholar

[59]

A Verma, A Parashar, M Packirisamy. Effect of grain boundaries on the interfacial behaviour of graphene-polyethylene nanocomposite. Appl Surf Sci 470: 1085- 1092 (2019)

Google Scholar

[60]

J M Zhan, X H Yao, W H Li, X Q Zhang. Tensile mechanical properties study of SiC/graphene composites based on molecular dynamics. Comp Mater Sci 131: 266-274 (2017)

Google Scholar

[61]

D R Klimek-McDonald, J A King, I Miskioglu, E J Pineda, G M Odegard. Determination and modeling of mechanical properties for graphene nanoplatelet/ epoxy composites. Polym Compos 39(6): 1845-1851 (2018)

Google Scholar

[62]

S C Shiu, J L Tsai. Characterizing thermal and mechanical properties of graphene/epoxy nanocomposites. Compos Part B: Eng 56: 691-697 (2014)

Google Scholar

[63]

G M Dai, L Mishnaevsky Jr. Graphene reinforced nanocomposites: 3D simulation of damage and fracture. Comp Mater Sci 95: 684-692 (2014)

Google Scholar

[64]

S Lee, J Y Hong, J Jang. The effect of graphene nanofiller on the crystallization behavior and mechanical properties of poly(vinyl alcohol). Polym Int 62(6): 901-908 (2013)

Google Scholar

[65]

B Das, K Eswar Prasad, U Ramamurty, C N R Rao. Nano-indentation studies on polymer matrix composites reinforced by few-layer graphene. Nanotechnology 20(12): 125705 (2009)

Google Scholar

[66]

B Y Du, O K C Tsui, Q L Zhang, T B He. Study of elastic modulus and yield strength of polymer thin films using atomic force microscopy. Langmuir 17(11): 3286- 3291 (2001)

Google Scholar

[67]

Z Yan, X L Shi, Y C Huang, X B Deng, X Y Liu, K Yang. Tribological performance of Ni₃Al matrix self-lubricating composites containing multilayer graphene prepared by additive manufacturing. J Mater Eng Perform 27(1): 167-175 (2018)

Google Scholar

[68]

L G Zhang, H M Qi, G T Li, D A Wang, T M Wang, Q H Wang, G Zhang. Significantly enhanced wear resistance of PEEK by simply filling with modified graphitic carbon nitride. Mater Design 129: 192-200 (2017)

Google Scholar

[69]

J P Salvetat-Delmotte, A Rubio. Mechanical properties of carbon nanotubes: A fiber digest for beginners. Carbon 40(10): 1729-1734 (2002)

Google Scholar

[70]

M F Ashby. Overview No. 80: On the engineering properties of materials. Acta Metall 37(5): 1273-1293 (1989)

Google Scholar

[71]

L B Zhang, JQ Wang, HG Wang, Y Xu, Z F Wang, Z P Li, Y J Mi, S R Yang. Preparation, mechanical and thermal properties of functionalized graphene/polyimide nanocomposites. Compos Part A: Appl Sci Manuf 43(9): 1537-1545 (2012)

Google Scholar

[72]

S Vadukumpully, J Paul, N Mahanta, S Valiyaveettil. Flexible conductive graphene/poly(vinyl chloride) composite thin films with high mechanical strength and thermal stability. Carbon 49(1): 198-205 (2011)

Google Scholar

[73]

X Wang, W Y Xing, X M Feng, B Yu, L Song, G H Yeoh, Y Hu. Enhanced mechanical and barrier properties of polyurethane nanocomposite films with randomly distributed molybdenum disulfide nanosheets. Compos Sci Technol 127: 142-148 (2016)

Google Scholar

[74]

J Suh, D Bae. Mechanical properties of polytetra-fluoroethylene composites reinforced with graphene nanoplatelets by solid-state processing. Compos Part B: Eng 95: 317-323 (2016)

Google Scholar

[75]

W L Wang, G X Sun, Y F Chen, X M Sun, J Q Bi. Preparation and mechanical properties of boron nitride nanosheets/alumina composites. Ceram Int 44(17): 21993-21997 (2018)

Google Scholar

[76]

L Q Jiang, H A Xie, Y Hou, S Wang, Y S Xia, Y Li, G H Hu, Q L Yang, C X Xiong, Z D F Gao. Enhanced piezoelectricity of a PVDF-based nanocomposite utilizing high-yield dispersions of exfoliated few-layer MoS₂. Ceram Int 45(9): 11347-11352 (2019)

Google Scholar

[77]

D D Zhang, Z J Zhan. Preparation of graphene nanoplatelets-copper composites by a modified semi-powder method and their mechanical properties. J Alloys Compd 658: 663-671 (2016)

Google Scholar

[78]

Z Q Duan, Y T Liu, X M Xie, X Y Ye. A simple and green route to transparent boron nitride/PVA nanocomposites with significantly improved mechanical and thermal properties. Chin Chem Lett 24(1): 17-19 (2013)

Google Scholar

[79]

M S R N Kiran, K Raidongia, U Ramamurty, C N R Rao. Improved mechanical properties of polymer nanocomposites incorporating graphene-like BN: Dependence on the number of BN layers. Scripta Mater 64(6): 592-595 (2011)

Google Scholar

[80]

M Krystek, D Pakulski, V Patroniak, M Górski, L Szojda, A Ciesielski, P Samorì. High-performance graphene-based cementitious composites. Adv Sci 6(9): 1801195 (2019)

Google Scholar

[81]

H Asgharzadeh, M Sedigh. Synthesis and mechanical properties of Al matrix composites reinforced with few-layer graphene and graphene oxide. J Alloys Compd 728: 47-62 (2017)

Google Scholar

[82]

R Saggar, H Porwal, P Tatarko, I Dlouhý, M J Reece. Boron nitride nanosheets reinforced glass matrix composites. Adv Appl Ceram 114(S1): S26-S33 (2015)

Google Scholar

[83]

U Khan, P May, A O'Neill, A P Bell, E Boussac, A Martin, J Semple, J N Coleman. Polymer reinforcement using liquid-exfoliated boron nitride nanosheets. Nanoscale 5(2): 581-587 (2013)

Google Scholar

[84]

K Q Zhou, S H Jiang, C L Bao, L Song, B B Wang, G Tang, Y Hu, Z Gui. Preparation of poly(vinyl alcohol) nanocomposites with molybdenum disulfide (MoS₂): Structural characteristics and markedly enhanced properties. RSC Adv 2(31): 11695-11703 (2012)

Google Scholar

[85]

S D Jiang, G Tang, Z M Bai, Y Y Wang, Y Hu, L Song. Surface functionalization of MoS₂ with POSS for enhancing thermal, flame-retardant and mechanical properties in PVA composites. RSC Adv 4(7): 3253- 3262 (2014)

Google Scholar

[86]

L Liu, Z G Shen, Y T Zheng, M Yi, X J Zhang, S L Ma. Boron nitride nanosheets with controlled size and thickness for enhancing mechanical properties and atomic oxygen erosion resistance. RSC Adv 4(71): 37726-37732 (2014)

Google Scholar

[87]

W J Meng, Y Huang, Y Q Fu, Z F Wang, C Y Zhi. Polymer composites of boron nitride nanotubes and nanosheets. J Mater Chem C 2(47): 10049-10061 (2014)

Google Scholar

[88]

Z H Cui, A P Martinez, D H Adamson. PMMA functionalized boron nitride sheets as nanofillers. Nanoscale 7(22): 10193-10197 (2015)

Google Scholar

[89]

D D Zhang, Z J Zhan. Experimental investigation of interfaces in graphene materials/copper composites from a new perspective. RSC Adv 6(57): 52219-52226 (2016)

Google Scholar

[90]

O S Kwon, D Lee, S P Lee, Y G Kang, N C Kim, S H Song. Enhancing the mechanical and thermal properties of boron nitride nanoplatelets/elastomer nanocomposites by latex mixing. RSC Adv 6(65): 59970-59975 (2016)

Google Scholar

[91]

C Zhao. Enhanced strength in reduced graphene oxide/nickel composites prepared by molecular-level mixing for structural applications. Appl Phys A 118(2): 409-416 (2015)

Google Scholar

[92]

H P Zhang, C Xu, W L Xiao, K Ameyama, C L Ma. Enhanced mechanical properties of Al5083 alloy with graphene nanoplates prepared by ball milling and hot extrusion. Mater Sci Eng: A 658: 8-15 (2016)

Google Scholar

[93]

Z H Yu, W S Yang, C Zhou, N B Zhang, Z L Chao, H Liu, Y F Cao, Y Sun, P Z Shao, G H Wu. Effect of ball milling time on graphene nanosheets reinforced Al6063 composite fabricated by pressure infiltration method. Carbon 141: 25-39 (2019)

Google Scholar

[94]

H Y Xia, X Zhang, Z Q Shi, C J Zhao, Y F Li, J P Wang, G J Qiao. Mechanical and thermal properties of reduced graphene oxide reinforced aluminum nitride ceramic composites. Mater Sci Eng: A 639: 29-36 (2015)

Google Scholar

[95]

J K Wu, C C Ye, T Liu, Q F An, Y H Song, K R Lee, W S Hung, C J Gao. Synergistic effects of CNT and GO on enhancing mechanical properties and separation performance of polyelectrolyte complex membranes. Mater Design 119: 38-46 (2017)

Google Scholar

[96]

F Z Wang, L T Drzal, Y Qin, Z X Huang. Mechanical properties and thermal conductivity of graphene nanoplatelet/epoxy composites. J Mater Sci 50(3): 1082- 1093 (2015)

Google Scholar

[97]

X Wang, H Y Yang, L Song, Y Hu, W Y Xing, H D Lu. Morphology, mechanical and thermal properties of graphene-reinforced poly(butylene succinate) nanocomposites. Compos Sci Technol 72(1): 1-6 (2011)

Google Scholar

[98]

Y J Wan, L X Gong, L C Tang, L B Wu, J X Jiang. Mechanical properties of epoxy composites filled with silane-functionalized graphene oxide. Compos Part A: Appl Sci Manuf 64: 79-89 (2014)

Google Scholar

[99]

Y X Tang, X M Yang, R R Wang, M X Li. Enhancement of the mechanical properties of graphene-copper composites with graphene-nickel hybrids. Mater Sci Eng: A 599: 247-254 (2014)

Google Scholar

[100]

D Lee, S H Song, J Hwang, S H Jin, K H Park, B H Kim, S H Hong, S Jeon. Enhanced mechanical properties of epoxy nanocomposites by mixing noncovalently functionalized boron nitride nanoflakes. Small 9(15): 2602-2610 (2013)

Google Scholar

[101]

X L Zhao, S H Qi, J J Liu, X Han, F Zhang. Preparation and mechanical performances of carbon fiber reinforced epoxy composites by Mxene nanosheets coating. J Mater Sci: Mater Electron 30(11): 10516-10523 (2019)

Google Scholar

[102]

R Surudžić, A Janković, N Bibić, M Vukašinović-Sekulić, A Perić-Grujić, V Mišković-Stanković, S J Park, K Y Rhee. Physico-chemical and mechanical properties and antibacterial activity of silver/poly(vinyl alcohol)/ graphene nanocomposites obtained by electrochemical method. Compos Part B: Eng 85: 102-112 (2016)

Google Scholar

[103]

T Rodenas, I Luz, G Prieto, B Seoane, H Miro, A Corma, F Kapteijn, I X F X Llabrés, J Gascon. Metal-organic framework nanosheets in polymer composite materials for gas separation. Nat Mater 14(1): 48-55 (2015)

Google Scholar

[104]

M H Al-Saleh, U Sundararaj. Review of the mechanical properties of carbon nanofiber/polymer composites. Compos Part A: Appl Sci Manuf 42(12): 2126-2142 (2011)

Google Scholar

[105]

C Elanchezhian, B V Ramnath, G Ramakrishnan, M Rajendrakumar, V Naveenkumar, M K Saravanakumar. Review on mechanical properties of natural fiber composites. Mater Today: Proc 5(1): 1785-1790 (2018)

Google Scholar

[106]

M D Frogley, D Ravich, H D Wagner. Mechanical properties of carbon nanoparticle-reinforced elastomers. Compos Sci Technol 63(11): 1647-1654 (2003)

Google Scholar

[107]

A C Balazs, T Emrick, T P Russell. Nanoparticle polymer composites: Where two small worlds meet. Science 314(5802): 1107-1110 (2006)

Google Scholar

[108]

L Zhang, G X Xie, S Wu, S G Peng, X Q Zhang, D Guo, S Z Wen, J B Luo. Ultralow friction polymer composites incorporated with monodispersed oil microcapsules. Friction, in press, .

Crossref Google Scholar

[109]

Y Zhao, B Liu, C You, M F Chen. Effects of MgO whiskers on mechanical properties and crystallization behavior of PLLA/MgO composites. Mater Design 89: 573-581 (2016)

Google Scholar

[110]

X C Wang, R F Song, Y J Chen, Y H Zhao, K Y Zhu, X Y Yuan. Mechanical properties of polypropylene by diversely compatibilizing with titanate whiskers in composites. Compos Sci Technol 164: 103-109 (2018)

Google Scholar

[111]

R Verdejo, M M Bernal, L J Romasanta, M A Lopez-Manchado. Graphene filled polymer nanocomposites. J Mater Chem 21(10): 3301-3310 (2011)

Google Scholar

[112]

M W Ahmad, B Dey, G Sarkhel, D S Bag, A Choudhury. Exfoliated graphene reinforced polybenzimidazole nanocomposite with improved electrical, mechanical and thermal properties. Mater Chem Phys 223: 426-433 (2019)

Google Scholar

[113]

L Y Zhang, S H Tu, H T Wang, Q G Du. Preparation of polymer/graphene oxide nanocomposites by a two-step strategy composed of in situ polymerization and melt processing. Compos Sci Technol 154: 1-7 (2018)

Google Scholar

[114]

M T Song, J Yang, S Kitipornchai. Bending and buckling analyses of functionally graded polymer composite plates reinforced with graphene nanoplatelets. Compos Part B: Eng 134: 106-113 (2018)

Google Scholar

[115]

Y J Ren, Y F Zhang, H M Fang, T P Ding, J L Li, S L Bai. Simultaneous enhancement on thermal and mechanical properties of polypropylene composites filled with graphite platelets and graphene sheets. Compos Part A: Appl Sci Manuf 112: 57-63 (2018)

Google Scholar

[116]

X D Zhang, J G Xu, H Wang, J J Zhang, H B Yan, B C Pan, J F Zhou, Y Xie. Ultrathin nanosheets of MAX phases with enhanced thermal and mechanical properties in polymeric compositions: Ti₃Si_0.75Al_0.25C₂. Angew Chem Int Ed Engl 52(16): 4361-4365 (2013)

Google Scholar

[117]

M A Rafiee, J Rafiee, Z Wang, H H Song, Z Z Yu, N Koratkar. Enhanced mechanical properties of nanocomposites at low graphene content. ACS Nano 3(12): 3884-3890 (2009)

Google Scholar

[118]

C Bora, P Gogoi, S Baglari, S K Dolui. Preparation of polyester resin/graphene oxide nanocomposite with improved mechanical strength. J Appl Polym Sci 129(6): 3432-3438 (2013)

Google Scholar

[119]

D Y Cai, J Jin, K Yusoh, R Rafiq, M Song. High performance polyurethane/functionalized graphene nanocomposites with improved mechanical and thermal properties. Compos Sci Technol 72(6): 702-707 (2012)

Google Scholar

[120]

Y Liu, H Wu, G H Chen. Enhanced mechanical properties of nanocomposites at low graphene content based on in situ ball milling. Polym Compos 37(4): 1190-1197 (2016)

Google Scholar

[121]

C Z Liu, S B Ye, J C Feng. Promoting the dispersion of graphene and crystallization of poly (lactic acid) with a freezing-dried graphene/PEG masterbatch. Compos Sci Technol 144: 215-222 (2017)

Google Scholar

[122]

C B Hatter, J Shah, B Anasori, Y Gogosi. Micromechanical response of two-dimensional transition metal carbonitride (MXene) reinforced epoxy composites. Compos Part B: Eng 182: 107603 (2020)

Google Scholar

[123]

L Jiang, X P Shen, J L Wu, K C Shen. Preparation and characterization of graphene/poly(vinyl alcohol) na-nocomposites. J Appl Polym Sci 118(1): 275-279 (2010)

Google Scholar

[124]

P Sobolčiak, A Ali, M K Hassan, M I Helal, A Tanvir, A Popelka, M A Al-Maadeed, K I Krupa, K A Mahmoud. 2D Ti₃C₂T_x (MXene)-reinforced polyvinyl alcohol (PVA) nanofibers with enhanced mechanical and electrical properties. PLoS One 12(8): e0183705 (2017)

Google Scholar

[125]

S A Mirkhani, A Shayesteh Zeraati, E Aliabadian, M Naguib, U Sundararaj. High dielectric constant and low dielectric loss via Poly(vinyl alcohol)/Ti₃C₂T_x MXene nanocomposites. ACS Appl Mater Interfaces 11(20): 18599-18608 (2019)

Google Scholar

[126]

R J Young, M F Liu, I A Kinloch, S H Li, X Zhao, C Vallés, D G Papageorgiou. The mechanics of reinforcement of polymers by graphene nanoplatelets. Compos Sci Technol 154: 110-116 (2018)

Google Scholar

[127]

P May, U Khan, A O'Neill, J N Coleman. Approaching the theoretical limit for reinforcing polymers with graphene. J Mater Chem 22(4): 1278-1282 (2012)

Google Scholar

[128]

Q Peng, W Ji, S De. Mechanical properties of the hexagonal boron nitride monolayer: Ab initio study. Comp Mater Sci 56: 11-17 (2012)

Google Scholar

[129]

S Wu, F He, G X Xie, Z L Bian, Y L Ren, X Y Liu, H J Yang, D Guo, L Zhang, S Z Wen, J B Luo, Super-slippery degraded black phosphorus/silicon dioxide interface. ACS Appl Mater Inter 12(6): 7717-7726 (2020)

Google Scholar

[130]

J Li, Y H Yin, Y Muhammad, J Yang, S Yang, H Q Yang, M Sahibzada. Preparation and properties of modified graphene oxide incorporated waterborne polyurethane acrylate. Polym Int 68(6): 1091-1101 (2019)

Google Scholar

[131]

M Fang, K G Wang, H B Lu, Y L Yang, S Nutt. Covalent polymer functionalization of graphenenanosheets and mechanical properties of composites. J Mater Chem 19(38): 7098-7105 (2009)

Google Scholar

[132]

L Zhang, Y F Li, H H Wang, Y D Qiao, J Z Chen, S K Cao. Strong and ductile poly(lactic acid) nanocomposite films reinforced with alkylated graphene nanosheets. Chem Eng J 264: 538-546 (2015)

Google Scholar

[133]

W H Liao, S Y Yang, S T Hsiao, Y S Wang, S M Li, C C M Ma, H W Tien, S J Zeng. Effect of octa(aminophenyl) polyhedral oligomeric silsesquioxane functionalized graphene oxide on the mechanical and dielectric properties of polyimide composites. ACS Appl Mater Interfaces 6(18): 15802-15812 (2014)

Google Scholar

[134]

X Y Ye, P W Gong, J Q Wang, H G Wang, S L Ren, S R Yang. Fluorinated graphene reinforced polyimide films with the improved thermal and mechanical properties. Compos Part A: Appl Sci Manuf 75: 96- 103 (2015)

Google Scholar

[135]

Y M Chen, X Gao, J L Wang, W He, V V Silberschmidt, S X Wang, Z H Tao, H Xu. Properties and application of polyimide-based composites by blending surface functionalized boron nitride nanoplates. J Appl Polym Sci 132(16): 41889 (2015)

Google Scholar

[136]

J Dong, C Q Yin, X Zhao, Y Z Li, Q H Zhang. High strength polyimide fibers with functionalized graphene. Polymer 54(23): 6415-6424 (2013)

Google Scholar

[137]

F Qiu, Y B Hao, X Y Li, B Wang, M Wang. Functionalized graphene sheets filled isotactic polypropylene nanocomposites. Compos Part B: Eng 71: 175-183 (2015)

Google Scholar

[138]

L X Xing, Q Li, G Z Zhang, X S Zhang, F H Liu, L Liu, Y D Huang, Q Wang. Self-healable polymer nanocomposites capable of simultaneously recovering multiple functionalities. Adv Funct Mater 26(20): 3524-3531 (2016)

Google Scholar

[139]

M T Chen, T Tao, L Zhang, W Gao, C Z Li. Highly conductive and stretchable polymer composites based on graphene/MWCNT network. Chem Commun 49(16): 1612-1614 (2013)

Google Scholar

[140]

Z L Li, J W Chu, C Yang, S J Hao, M A Bissett, I A Kinloch, R J Young. Effect of functional groups on the agglomeration of graphene in nanocomposites. Compos Sci Technol 163: 116-122 (2018)

Google Scholar

[141]

O F Damnalı,, V Eskizeybek. Synergistic impact of graphene and carbon nanotubes on waste paper for hybrid nanocomposite substrates. Cellulose 26(6): 3935-3954 (2019)

Google Scholar

[142]

V B Mohan, R Brown, K Jayaraman, D Bhattacharyya. Optimisation of hybridisation effect in graphene reinforced polymer nanocomposites. Adv Compos Mater 27(4): 349-365 (2018)

Google Scholar

[143]

X L Cui, P Ding, N Zhuang, L Y Shi, N Song, S F Tang. Thermal conductive and mechanical properties of polymeric composites based on solution-exfoliated boron nitride and graphene nanosheets: A morphology-promoted synergistic effect. ACS Appl Mater Interfaces 7(34): 19068-19075 (2015)

Google Scholar

[144]

S Wu, F He, G X Xie, Z L Bian, J B Luo, S Z Wen. Black phosphorus: Degradation favors lubrication. Nano Lett 18(9): 5618-5627 (2018)

Google Scholar

[145]

Z Z Zhang, M M Yang, J Y Yuan, F Guo, X H Men. Friction and wear behaviors of MoS₂-multi-walled-carbonnanotube hybrid reinforced polyurethane composite coating. Friction 7(4): 316-326 (2019)

Google Scholar

[146]

G L Zhang, G X Xie, L N Si, S Z Wen, D Guo. Ultralow friction self-lubricating nanocomposites with mesoporous metal-organic frameworks as smart nanocontainers for lubricants. ACS Appl Mater Interfaces 9(43): 38146- 38152 (2017)

Google Scholar

[147]

S G Peng, Y Guo, G X Xie, J B Luo. Tribological behavior of polytetrafluoroethylene coating reinforced with black phosphorus nanoparticles. Appl Surf Sci 441: 670-677 (2018)

Google Scholar

[148]

S Bhargava, N Koratkar, T A Blanchet. Effect of platelet thickness on wear of graphene-polytetrafluoroethylene (PTFE) composites. Tribol Lett 59(1): 17 (2015)

Google Scholar

[149]

S Li, C J Duan, X Li, M C Shao, C H Qu, D Zhang, Q H Wang, T M Wang, X R Zhang. The effect of different layered materials on the tribological properties of PTFE composites. Friction 8(3): 542-552 (2020)

Google Scholar

[150]

Y Lv, W Wang, G X Xie, J B Luo. Self-lubricating PTFE-based composites with black phosphorus nanosheets. Tribol Lett 66(2): 61 (2018)

Google Scholar

[151]

J Chen, B Chen, J Y Li, X Tong, H C Zhao, L P Wang. Enhancement of mechanical and wear resistance performance in hexagonal boron nitride-reinforced epoxy nanocomposites. Polym Int 66(5): 659-664 (2017)

Google Scholar

[152]

Y J Min, K H Kang, D E Kim. Development of polyimide films reinforced with boron nitride and boron nitride nanosheets for transparent flexible device applications. Nano Res 11(5): 2366-2378 (2018)

Google Scholar

[153]

M M Yang, Z Z Zhang, X T Zhu, X H Men, G N Ren. In situ reduction and functionalization of graphene oxide to improve the tribological behavior of a phenol formaldehyde composite coating. Friction 3(1): 72-81 (2015)

Google Scholar

[154]

S L Qiu, Y X Hu, Y Q Shi, Y B Hou, Y C Kan, F K Chu, H B Sheng, R K K Yuen, W Y Xing. In situ growth of polyphosphazene particles on molybdenum disulfide nanosheets for flame retardant and friction application. Compos Part A: Appl Sci Manuf 114: 407-417 (2018)

Google Scholar

[155]

Z Y Chen, H X Yan, L L Guo, L Li, P F Yang, B Liu. A novel polyamide-type cyclophosphazene functionalized rGO/WS₂ nanosheets for bismaleimide resin with enhanced mechanical and tribological properties. Compos Part A: Appl Sci Manuf 121: 18-27 (2019)

Google Scholar

[156]

H Zhang, L B Wang, Q Chen, P Li, A G Zhou, X X Cao, Q K Hu. Preparation, mechanical and anti-friction performance of MXene/polymer composites. Mater Design 92: 682-689 (2016)

Google Scholar

[157]

S S Kandanur, M A Rafiee, F Yavari, M Schrameyer, Z Z Yu, T A Blanchet, N Koratkar. Suppression of wear in graphene polymer composites. Carbon 50(9): 3178- 3183 (2012)

Google Scholar

[158]

D Lahiri, F Hec, M Thiesse, A Durygin, C Zhang, A Agarwal. Nanotribological behavior of graphene nanoplatelet reinforced ultra high molecular weight polyethylene composites. Tribol Int 70: 165-169 (2014)

Google Scholar

[159]

J Zhao, G Y Chen, Y Y He, S X Li, Z Q Duan, Y R Li, J B Luo. A novel route to the synthesis of an Fe₃O₄/ h-BN 2D nanocomposite as a lubricant additive. RSC Adv 9(12): 6583-6588 (2019)

Google Scholar

[160]

Z Xu, W J Lou, G Q Zhao, Q Zhao, N Xu, J Y Hao, X B Wang. Preparation of WS₂ nanocomposites via mussel-inspired chemistry and their enhanced dispersion stability and tribological performance in polyalkylene glycol. J Dispersion Sci Technol 40(5): 737-744 (2019)

Google Scholar

[161]

F Chen, D Q Jin, K Tyeb, B T Wang, Y H Han, S Kim, J M Schoenung, Q Shen, L M Zhang. Field assisted sintering of graphene reinforced zirconia ceramics. Ceram Int 41(4): 6113-6116 (2015)

Google Scholar

[162]

Y C Fan, G Igarashi, W Jiang, L J Wang, A Kawasaki. Highly strain tolerant and tough ceramic composite by incorporation of graphene. Carbon 90: 274-283 (2015)

Google Scholar

[163]

X Liu, Y C Fan, J L Li, L J Wang, W Jiang. Preparation and mechanical properties of graphene nanosheet reinforced alumina composites. Adv Eng Mater 17(1): 28-35 (2015)

Google Scholar

[164]

Z Pan, L He, L Qiu, A H Korayem, G Li, J W Zhu, F Collins, D Li, W H Duan, M C Wang. Mechanical properties and microstructure of a graphene oxide-cement composite. Cem Concr Compos 58: 140-147 (2015)

Google Scholar

[165]

P Rutkowski, L Stobierski, D Zientara, L Jaworska, P Klimczyk, M Urbanik. The influence of the graphene additive on mechanical properties and wear of hot-pressed Si₃N₄ matrix composites. J Eur Ceram Soc 35(1): 87-94 (2015)

Google Scholar

[166]

C Yun, Y B Feng, T Qiu, J Yang, X Y Li, L Yu. Mechanical, electrical, and thermal properties of graphene nanosheet/aluminum nitride composites. Ceram Int 41(7): 8643-8649 (2015)

Google Scholar

[167]

X P Han, Y Huang, S H Zhou, X Sun, X Y Peng, X F Chen. Effects of graphene content on thermal and mechanical properties of chromium-coated graphite flakes/Si/Al composites. J Mater Sci: Mater Electron 29(5): 4179- 4189 (2018)

Google Scholar

[168]

R Cano-Crespo, B M Moshtaghioun, D Gómez-García, R Moreno, A Domínguez-Rodríguez. Graphene or carbon nanofiber-reinforced zirconia composites: Are they really worthwhile for structural applications? J Eur Ceram Soc 38(11): 3994-4002 (2018)

Google Scholar

[169]

Z B Yin, J T Yuan, W W Xu, K Liu, S Y Yan. Graphene nanosheets toughened TiB₂-based ceramic tool material by spark plasma sintering. Ceram Int 44(8): 8977- 8982 (2018)

Google Scholar

[170]

Y M An, X H Xu, K X Gui. Effect of SiC whiskers and graphene nanosheets on the mechanical properties of ZrB₂ -SiC_w-Graphene ceramic composites. Ceram Int 42(12): 14066-14070 (2016)

Google Scholar

[171]

K Markandan, J K Chin, M T T Tan. Recent progress in graphene based ceramic composites: A review. J Mater Res 32(1): 84-106 (2017)

Google Scholar

[172]

A Nieto, A Bisht, D Lahiri, C Zhang, A Agarwal. Graphene reinforced metal and ceramic matrix composites: A review. Int Mater Rev 62(5): 241-302 (2017)

Google Scholar

[173]

M Birenboim, R Nadiv, A Alatawna, M Buzaglo, G Schahar, J Lee, et al. Reinforcement and workability aspects of graphene-oxide-reinforced cement nanocomposites. Compos Part B: Eng 161: 68-76 (2019)

Google Scholar

[174]

Y J Li, B Z Ge, Z H Wu, G Q Xiao, Z Q Shi, Z H Jin. Effects of h-BN on mechanical properties of reaction bonded β-SiAlON/h-BN composites. J Alloys Compd 703: 180-187 (2017)

Google Scholar

[175]

Q Li, D L Cai, Z H Yang, X M Duan, D X Li, Y S Sun, S J Wang, D C Jia, B Joachim, Y Zhou. Effects of BN on the microstructural evolution and mechanical properties of BAS-BN composites. Ceram Int 45(2): 1627-1633 (2019)

Google Scholar

[176]

M M Fei, R Z Lin, Y W Lu, X L Zhang, R J Bian, J G Cheng, P F Luo, C X Xu, D Y Cai. MXene-reinforced alumina ceramic composites. Ceram Int 43(18): 17206-17210 (2017)

Google Scholar

[177]

J Guo, B Legum, B Anasori, K Wang, P Lelyukh, Y Gogotsi, C A Randall. Cold sintered ceramic nanocomposites of 2D MXene and zinc oxide. Adv Mater 30(32): 1801846 (2018)

Google Scholar

[178]

M Belmonte, C Ramírez, J González-Julián, J Schneider, P Miranzo, M I Osendi. The beneficial effect of graphene nanofillers on the tribological performance of ceramics. Carbon 61: 431-435 (2013)

Google Scholar

[179]

H Porwal, P Tatarko, R Saggar, S Grasso, M Kumar Mani, I Dlouhý, J Dusza, M J Reece. Tribological properties of silica-graphene nano-platelet composites. Ceram Int 40(8): 12067-12074 (2014)

Google Scholar

[180]

Z Y B Zeng, Y Z Liu, R R Guo, K L Li. Friction and wear behaviours of in situ reduced graphene oxide reinforced zirconia ceramic. Int J Refract Met Hard Mater 79: 164-170 (2019)

Google Scholar

[181]

J Llorente, C Ramírez, M Belmonte. High graphene fillers content for improving the tribological performance of silicon nitride-based ceramics. Wear 430-431: 183-190 (2019)

Google Scholar

[182]

Y F Su, Y S Zhang, J J Song, L T Hu. Novel approach to the fabrication of an alumina-MoS₂ self-lubricating composite via the in situ synthesis of nanosized MoS₂. ACS Appl Mater Interfaces 9(36): 30263-30266 (2017)

Google Scholar

[183]

E C Serra, V F D Soares, D A R Fernandez, R Hübler, K R C Juste, C L Lima, E K Tentardini. Influence of WS₂ content on high temperature wear performance of magnetron sputtered TiN-WS_x thin films. Ceram Int 45(16): 19918-19924 (2019)

Google Scholar

[184]

W L Zhang, C Schröder, B Schlüter, M Knoch, J Dusza, R Sedlák, R Mülhaupt, A Kailer. Effect of mechanochemically functionalized multilayer graphene on the tribological properties of silicon carbide/ graphene nanocomposites in aqueous environment. Tribol Lett 66(4): 121 (2018)

Google Scholar

[185]

H J Kim, S M Lee, Y S Oh, Y H Yang, Y S Lim, D H Yoon, C Lee, J Y Kim, R S Ruoff. Unoxidized graphene/alumina nanocomposite: Fracture-and wear-resistance effects of graphene on alumina matrix. Sci Rep 4(1): 5176 (2015)

Google Scholar

[186]

J Llorente, M Belmonte. Friction and wear behaviour of silicon carbide/graphene composites under isooctane lubrication. J Eur Ceram Soc 38(10): 3441-3446 (2018)

Google Scholar

[187]

J Dutkiewicz, P Ozga, W Maziarz, J Pstruś, B Kania, P Bobrowski, J Stolarska. Microstructure and properties of bulk copper matrix composites strengthened with various kinds of graphene nanoplatelets. Mater Sci Eng: A 628: 124-134 (2015)

Google Scholar

[188]

M X Li, J Xie, Y D Li, H H Xu. Reduced graphene oxide dispersed in copper matrix composites: Facile preparation and enhanced mechanical properties. Phys Status Solidi A 212(10): 2154-2161 (2015)

Google Scholar

[189]

X Gao, H Y Yue, E J Guo, H Zhang, X Y Lin, L H Yao, B Wang. Mechanical properties and thermal conductivity of graphene reinforced copper matrix composites. Powder Technol 301: 601-607 (2016)

Google Scholar

[190]

Y K Chen, X Zhang, E Z Liu, C N He, C S Shi, J J Li, P Nash, N Q Zhao. Fabrication of in-situ grown graphene reinforced Cu matrix composites. Sci Rep 6(1): 19363 (2016)

Google Scholar

[191]

L D Wang, Z Y Yang, Y Cui, B Wei, S C Xu, J Sheng, M Wang, Y P Zhu, W D Fei. Graphene-copper composite with micro-layered grains and ultrahigh strength. Sci Rep 7(1): 41896 (2017)

Google Scholar

[192]

M Rashad, F S Pan, Z W Yu, M Asif, H Lin, R J Pan. Investigation on microstructural, mechanical and electrochemical properties of aluminum composites reinforced with graphene nanoplatelets. Prog Nat Sci: Mater 25(5): 460-470 (2015)

Google Scholar

[193]

Z Li, Q Guo, Z Q Li, G L Fan, D B Xiong, Y S Su, J Zhang, D Zhang. Enhanced mechanical properties of graphene (reduced graphene oxide)/aluminum composites with a bioinspired nanolaminated structure. Nano Lett 15(12): 8077-8083 (2015)

Google Scholar

[194]

B L Dasari, M Morshed, J M Nouri, D Brabazon, S Naher. Mechanical properties of graphene oxide reinforced aluminium matrix composites. Compos Part B: Eng 145: 136-144 (2018)

Google Scholar

[195]

M Rashad, F S Pan, A T Tang, M Asif, J She, J Gou, J J Mao, H H Hu. Development of magnesium-graphene nanoplatelets composite. J Compos Mater 49(3): 285-293 (2015)

Google Scholar

[196]

Z D Ren, N Meng, K Shehzad, Y Xu, S X Qu, B Yu, J K Luo. Mechanical properties of nickel-graphene composites synthesized by electrochemical deposition. Nanotechnology 26(6): 065706 (2015)

Google Scholar

[197]

Z S Xu, X L Shi, W Z Zhai, J Yao, S Y Song, Q X Zhang. Preparation and tribological properties of TiAl matrix composites reinforced by multilayer graphene. Carbon 67: 168-177 (2014)

Google Scholar

[198]

P Hidalgo-Manrique, X Z Lei, R Y Xu, M Y Zhou, I A Kinloch, R J Young. Copper/graphene composites: A review. J Mater Sci 54(19): 12236-12289 (2019)

Google Scholar

[199]

V B Mohan, K T Lau, D Hui, D Bhattacharyya. Graphene-based materials and their composites: A review on production, applications and product limitations. Compos Part B: Eng 142: 200-220 (2018)

Google Scholar

[200]

Z Hu, G Tong, D Lin, C Chen, H Guo, J Xu, L Zhou. Graphene-reinforced metal matrix nanocomposites— A review. Mater Sci Technol 32(9): 930-953 (2016)

Google Scholar

[201]

L Q Wu, R Z Wu, L G Hou, J H Zhang, M L Zhang. Microstructure, mechanical properties and wear performance of AZ31 matrix composites reinforced by graphene nanoplatelets(GNPs). J Alloys Compd 750: 530-536 (2018)

Google Scholar

[202]

A Dorri Moghadam, E Omrani, P L Menezes, P K Rohatgi. Mechanical and tribological properties of self-lubricating metal matrix nanocomposites reinforced by carbon nanotubes (CNTs) and graphene-A review. Compos Part B: Eng 77: 402-420 (2015)

Google Scholar

[203]

M Rashad, F S Pan, H H Hu, M Asif, S Hussain, J She. Enhanced tensile properties of magnesium composites reinforced with graphene nanoplatelets. Mater Sci Eng: A 630: 36-44 (2015)

Google Scholar

[204]

D B Xiong, M Cao, Q Guo, Z Q Tan, G L Fan, Z Q Li, D Zhang. Graphene-and-copper artificial nacre fabricated by a preform impregnation process: Bioinspired strategy for strengthening-toughening of metal matrix composite. ACS Nano 9(7): 6934-6943 (2015)

Google Scholar

[205]

Y Song, Y Chen, W W Liu, W L Li, Y G Wang, D Zhao, X B Liu. Microscopic mechanical properties of titanium composites containing multi-layer graphene nanofillers. Mater Design 109: 256-263 (2016)

Google Scholar

[206]

D D Zhang, Z J Zhan. Strengthening effect of graphene derivatives in copper matrix composites. J Alloys Compd 654: 226-233 (2016)

Google Scholar

[207]

S Kumar. Graphene engendered aluminium crystal growth and mechanical properties of its composite: An atomistic investigation. Mater Chem Phys 208: 41-48 (2018)

Google Scholar

[208]

Y Z Wan, Y L Wang, H L Luo, X H Dong, G X Cheng. Effects of fiber volume fraction, hot pressing parameters and alloying elements on tensile strength of carbon fiber reinforced copper matrix composite prepared by continuous three-step electrodeposition. Mater Sci Eng: A 288(1): 26-33 (2000)

Google Scholar

[209]

S I Cha, K T Kim, S N Arshad, C B Mo, S H Hong. Extraordinary strengthening effect of carbon nanotubes in metal-matrix nanocomposites processed by molecular-level mixing. Adv Mater 17(11): 1377-1381 (2005)

Google Scholar

[210]

K Munir, C Wen, Y Li. Graphene nanoplatelets-reinforced magnesium metal matrix nanocomposites with superior mechanical and corrosion performance for biomedical applications. J Magnes Alloy 8(1): 269-290 (2020)

Google Scholar

[211]

K Chu, F Wang, Y B Li, X H Wang, D J Huang, Z R Geng. Interface and mechanical/thermal properties of graphene/copper composite with Mo₂C nanoparticles grown on graphene. Compos Part A: Appl Sci Manuf 109: 267-279 (2018)

Google Scholar

[212]

Z F Jia, H Q Li, Y Zhao, L Frazer, B S Qian, E Borguet, F Ren, D A Dikin. Electrical and mechanical properties of poly(dopamine)-modified copper/reduced graphene oxide composites. J Mater Sci 52(19): 11620-11629 (2017)

Google Scholar

[213]

X Y Zhao, J C Tang, F X Yu, N Ye. Preparation of graphene nanoplatelets reinforcing copper matrix composites by electrochemical deposition. J Alloys Compd 766: 266-273 (2018)

Google Scholar

[214]

M Arab, S P H Marashi. Effect of graphene nanoplatelets (GNPs) content on improvement of mechanical and tribological properties of AZ31 Mg matrix nanocomposite. Tribol Int 132: 1-10 (2019)

Google Scholar

[215]

N Khobragade, K Sikdar, B Kumar, S Bera, D Roy. Mechanical and electrical properties of copper-graphene nanocomposite fabricated by high pressure torsion. J Alloys Compd 776: 123-132 (2019)

Google Scholar

[216]

K Chu, Y P Liu, J Wang, Z R Geng, Y B Li. Oxygen plasma treatment for improving graphene distribution and mechanical properties of graphene/copper composites. Mater Sci Eng: A 735: 398-407 (2018)

Google Scholar

[217]

Y B Zhao, X H Peng, T Fu, X F Zhu, N Hu, C Yan. Strengthening mechanisms of graphene coated copper under nanoindentation. Comp Mater Sci 144: 42-49 (2018)

Google Scholar

[218]

X Gao, H Y Yue, E J Guo, H Zhang, X Y Lin, L H Yao, B Wang. Preparation and tensile properties of homogeneously dispersed graphene reinforced aluminum matrix composites. Mater Design 94: 54-60 (2016)

Google Scholar

[219]

K Fu, X Zhang, C S Shi, E Z Liu, F He, J J Li, N Q Zhao, C N He. An approach for fabricating Ni@graphene reinforced nickel matrix composites with enhanced mechanical properties. Mater Sci Eng: A 715: 108-116 (2018)

Google Scholar

[220]

X Gao, H Y Yue, E J Guo, S L Zhang, L H Yao, X Y Lin, B Wang, E H Guan. Tribological properties of copper matrix composites reinforced with homogeneously dispersed graphene nanosheets. J Mater Sci Technol 34(10): 1925-1931 (2018)

Google Scholar

[221]

S Zhang, T B Ma, A Erdemir, Q Y Li. Tribology of two-dimensional materials: From mechanisms to modulating strategies. Mater Today 26: 67-86 (2019)

Google Scholar

[222]

Y J Mai, Y G Li, S L Li, L Y Zhang, C S Liu, X H Jie. Self-lubricating Ti₃C₂ nanosheets/copper composite coatings. J Alloys Compd 770: 1-5 (2019)

Google Scholar

[223]

S Y Wang, S B Han, G Q Xin, J L Lin, R H Wei, J Lian, K Sun, X T Zu, Q K Yu. High-quality graphene directly grown on Cu nanoparticles for Cu-graphene nanocomposites. Mater Design 139: 181-187 (2018)

Google Scholar

[224]

Y J Mai, F X Chen, W Q Lian, L Y Zhang, C S Liu, X H Jie. Preparation and tribological behavior of copper matrix composites reinforced with nickel nanoparticles anchored graphene nanosheets. J Alloys Compd 756: 1-7 (2018)

Google Scholar

[225]

Y Lei, J L Jiang, T T Bi, J F Du, X J Pang. Tribological behavior of in situ fabricated graphene-nickel matrix composites. RSC Adv 8(39): 22113-22121 (2018)

Google Scholar

[226]

J Wozniak, M Kostecki, T Cygan, M Buczek, A Olszyna. Self-lubricating aluminium matrix composites reinforced with 2D crystals. Compos Part B: Eng 111: 1-9 (2017)

Google Scholar

[227]

A Loganathan, S Rengifo, A F Hernandez, Y Emirov, C Zhang, B Boesl, J Karthikeyan, A Agarwal. Effect of 2D WS₂ addition on cold-sprayed aluminum coating. J Therm Spray Technol 26(7): 1585-1597 (2017)

Google Scholar

[228]

W Z Zhai, X L Shi, J Yao, A M M Ibrahim, Z S Xu, Q S Zhu, Y C Xiao, L Chen, Q X Zhang. Investigation of mechanical and tribological behaviors of multilayer graphene reinforced Ni₃Al matrix composites. Compos Part B: Eng 70: 149-155 (2015)

Google Scholar

[229]

W Z Zhai, N Srikanth, L B Kong, K Zhou. Carbon nanomaterials in tribology. Carbon 119: 150-171 (2017)

Google Scholar

[230]

J F Wang, X X Jin, C H Li, W J Wang, H Wu, S Y Guo. Graphene and graphene derivatives toughening polymers: Toward high toughness and strength. Chem Eng J 370: 831-854 (2019)

Google Scholar

[231]

A Hussein, B Kim. Graphene/polymer nanocomposites: The active role of the matrix in stiffening mechanics. Compos Struct 202: 170-181 (2018)

Google Scholar

[232]

T Huang, Y S Xin, T S Li, S Nutt, C Su, H M Chen, P Liu, Z L Lai. Modified graphene/polyimide nanocomposites: Reinforcing and tribological effects. ACS Appl Mater Interfaces 5(11): 4878-4891 (2013)

Google Scholar

[233]

Y L Li, S J Wang, Q Wang, M Xing. A comparison study on mechanical properties of polymer composites reinforced by carbon nanotubes and graphene sheet. Compos Part B: Eng 133: 35-41 (2018)

Google Scholar

[234]

J T Hu, Y Huang, X L Zeng, Q Li, L L Ren, R Sun, J B Xu, C P Wong. Polymer composite with enhanced thermal conductivity and mechanical strength through orientation manipulating of BN. Compos Sci Technol 160: 127-137 (2018)

Google Scholar

[235]

M M Fei, R Z Lin, Y M Deng, H X Xian, R J Bian, X L Zhang, J G Cheng, C X Xu, D Y Cai. Polybenzimidazole/Mxene composite membranes for intermediate temperature polymer electrolyte membrane fuel cells. Nanotechnology 29(3): 035403 (2018)

Google Scholar

[236]

M B Khan, R Jan, A Habib, A N Khan. Evaluating mechanical properties of few layers MoS₂ nanosheets-polymer composites. Adv Mater Sci Eng 2017: 3176808 (2017)

Google Scholar

[237]

M F Liu, D G Papageorgiou, S H Li, K L Lin, I A Kinloch, R J Young. Micromechanics of reinforcement of a graphene-based thermoplastic elastomer nanocomposite. Compos Part A: Appl Sci Manuf 110: 84-92 (2018)

Google Scholar

[238]

H M Fang, S L Bai, C P Wong. Thermal, mechanical and dielectric properties of flexible BN foam and BN nanosheets reinforced polymer composites for electronic packaging application. Compos Part A: Appl Sci Manuf 100: 71-80 (2017)

Google Scholar

[239]

H B Luo, Y W Sui, J Q Qi, Q K Meng, F X Wei, Y Z He. Mechanical enhancement of copper matrix composites with homogeneously dispersed graphene modified by silver nanoparticles. J Alloys Compd 729: 293-302 (2017)

Google Scholar

[240]

U Khan, P May, A O’Neill, J N Coleman. Development of stiff, strong, yet tough composites by the addition of solvent exfoliated graphene to polyurethane. Carbon 48(14): 4035-4041 (2010)

Google Scholar

[241]

A O’Neill, U Khan, J N Coleman. Preparation of high concentration dispersions of exfoliated MoS₂ with increased flake size. Chem Mater 24(12): 2414-2421 (2012)

Google Scholar

[242]

X Y Ren, X Yang, G X Xie, J B Luo. Black Phosphorus Quantum Dots in Aqueous Ethylene Glycol for Macroscale Superlubricity. ACS Appl Nano Mater, in Press, .

Crossref Google Scholar

[243]

J A King, D R Klimek, I Miskioglu, G M Odegard. Mechanical properties of graphene nanoplatelet/epoxy composites. J Compos Mater 49(6): 659-668 (2015)

Google Scholar

[244]

S V Polschikov, P M Nedorezova, A N Klyamkina, A A Kovalchuk, A M Aladyshev, A N Shchegolikhin, V G Shchegolikhin, V E Muradyan. Composite materials of graphene nanoplatelets and polypropylene, prepared by in situ polymerization. J Appl Polym Sci 127(2): 904-911 (2013)

Google Scholar

[245]

P Costa, J Nunes-Pereira, J Oliveira, J Silva, J A Moreira, S A C Carabineiro, J G Buijnsters, S Lanceros-Mendez. High-performance graphene-based carbon nanofiller/polymer composites for piezoresistive sensor applications. Compos Sci Technol 153: 241-252 (2017)

Google Scholar

[246]

P G Ren, Y Y Di, Q Zhang, L Li, H Pang, Z M Li. Composites of ultrahigh-molecular-weight polyethylene with graphene sheets and/or MWCNTs with segregated network structure: Preparation and properties. Macromol Mater Eng 297(5): 437-443 (2012)

Google Scholar

[247]

Y C Yang, W Rigdon, X Y Huang, X D Li. Enhancing graphene reinforcing potential in composites by hydrogen passivation induced dispersion. Sci Rep 3(1): 2086 (2013)

Google Scholar

[248]

R R Jiang, X F Zhou, Q L Fang, Z P Liu. Copper-graphene bulk composites with homogeneous graphene dispersion and enhanced mechanical properties. Mater Sci Eng: A 654: 124-130 (2016)

Google Scholar

[249]

N V Ponraj, S C Vettivel, A Azhagurajan, X Sahaya Shajan, P Y Nabhiraj, T Theivasanthi, P Selvakumar, A H Lenin. Effect of milling on dispersion of graphene nanosheet reinforcement in different morphology copper powder matrix. Surf Interfaces 9: 260-265 (2017)

Google Scholar

[250]

A Saboori, S K Moheimani, M Dadkhah, M Pavese, C Badini, P Fino. An overview of key challenges in the fabrication of metal matrix nanocomposites reinforced by graphene nanoplatelets. Metals 8(3): 172 (2018)

Google Scholar

[251]

Z L Li, R J Young, N R Wilson, I A Kinloch, C Vallés, Z Li. Effect of the orientation of graphene-based nanoplatelets upon the Young's modulus of nanocomposites. Compos Sci Technol 123: 125-133 (2016)

Google Scholar

[252]

T Huang, R G Lu, C Su, H N Wang, Z Guo, P Liu, Z Y Huang, H M Chen, T S Li. Chemically modified graphene/polyimide composite films based on utilization of covalent bonding and oriented distribution. ACS Appl Mater Interfaces 4(5): 2699-2708 (2012)

Google Scholar

[253]

K Chu, F Wang, X H Wang, D J Huang. Anisotropic mechanical properties of graphene/copper composites with aligned graphene. Mater Sci Eng: A 713: 269-277 (2018)

Google Scholar

[254]

R Jan, P May, A P Bell, A Habib, U Khan, J N Coleman. Enhancing the mechanical properties of BN nanosheet-polymer composites by uniaxial drawing. Nanoscale 6(9): 4889-4895 (2014)

Google Scholar

[255]

F Wang, H Y Wang, J Mao. Aligned-graphene composites: A review. J Mater Sci 54(1): 36-61 (2019)

Google Scholar

[256]

J R Wu, G S Huang, H Li, S D Wu, Y F Liu, J Zheng. Enhanced mechanical and gas barrier properties of rubber nanocomposites with surface functionalized graphene oxide at low content. Polymer 54(7): 1930- 1937 (2013)

Google Scholar

[257]

Y L Zhang, Y Wang, J R Yu, L Chen, J Zhu, Z M Hu. Tuning the interface of graphene platelets/epoxy composites by the covalent grafting of polybenzimidazole. Polymer 55(19): 4990-5000 (2014)

Google Scholar

[258]

S Chhetri, N C Adak, P Samanta, P K Mallisetty, N C Murmu, T Kuila. Interface engineering for the improvement of mechanical and thermal properties of covalent functionalized graphene/epoxy composites. J Appl Polym Sci 135(15): 46124 (2018)

Google Scholar

[259]

H Chen, D Guo, G X Xie, G S Pan. Mechanical model of nanoparticles for material removal in chemical mechanical polishing process. Friction 4(2): 153-164 (2016)

Google Scholar

[260]

M J Buehler, A Misra. Mechanical behavior of nanocomposites. MRS Bull 44(1): 19-24 (2019)

Google Scholar

[261]

Z Y Lu, A Hanif, G X Sun, R Liang, P Parthasarathy, Z J Li. Highly dispersed graphene oxide electrodeposited carbon fiber reinforced cement-based materials with enhanced mechanical properties. Cem Concr Compos 87: 220-228 (2018)

Google Scholar

[262]

L Chen, S G Chai, K Liu, N Y Ning, J Gao, Q F Liu, F Chen, Q Fu. Enhanced epoxy/silica composites mechanical properties by introducing graphene oxide to the interface. ACS Appl Mater Interfaces 4(8): 4398- 4404 (2012)

Google Scholar

[263]

J J Lewandowski, M Seifi. Metal additive manufacturing: A review of mechanical properties. Annu Rev Mater Res 46(1): 151-186 (2016)

Google Scholar

[264]

M Naguib, V N Mochalin, M W Barsoum, Y Gogotsi. 25th anniversary article: MXenes: A new family of two-dimensional materials. Adv Mater 26(7): 992- 1005 (2014)

Google Scholar

[265]

S Das, D Pandey, J Thomas, T Roy. The role of graphene and other 2D materials in solar photovoltaics. Adv Mater 31(1): 1802722 (2018)

Google Scholar

[266]

Z Y Wang, B X Mi. Environmental applications of 2D molybdenum disulfide (MoS₂) nanosheets. Environ. Sci. Technol. 51(15): 8229-8244 (2017)

Google Scholar

[267]

M G Campbell, D Sheberla, S F Liu, T M Swager, M Dincă. Cu₃(hexaiminotriphenylene)₂: An electrically conductive 2D metal-organic framework for chemiresistive sensing. Angew Chem Int Ed Engl 54(14): 4349-4352 (2015)

Google Scholar

[268]

X W Yu, H H Cheng, M Zhang, Y Zhao, L T Qu, G Q Shi. Graphene-based smart materials. Nat Rev Mater 2(9): 17046 (2017)

Google Scholar

[269]

A Hazarika, B K Deka, D Y Kim, H E Jeong, Y B Park, H W Park. Woven kevlar fiber/polydimethylsiloxane/ reduced graphene oxide composite-based personal thermal management with freestanding Cu-Ni core-shell nanowires. Nano Lett 18(11): 6731-6739 (2018)

Google Scholar

[270]

I Vlassiouk, G Polizos, R Cooper, I Ivanov, J K Keum, F Paulauskas, P Datskos, S Smirnov. Strong and electrically conductive graphene-based composite fibers and laminates. ACS Appl Mater Interfaces 7(20): 10702-10709 (2015)

Google Scholar

[271]

D Trache, M H Hussin, C T Hui Chuin, S Sabar, M R N Fazita, O F A Taiwo, T M Hassan, M K M Haafiz. Microcrystalline cellulose: Isolation, characterization and bio-composites application—A review. Int J Biol Macromol 93: 789-804 (2016)

Google Scholar

[272]

Y F Dong, Z S Wu, W C Ren, H M Cheng, X H Bao. Graphene: A promising 2D material for electrochemical energy storage. Sci Bull 62(10): 724-740 (2017)

Google Scholar

[273]

C Cha, S R Shin, N Annabi, M R Dokmeci, A Khademhosseini. Carbon-based nanomaterials: Multifunctional materials for biomedical engineering. ACS Nano 7(4): 2891-2897 (2013)

Google Scholar

[274]

S Goenka, V Sant, S Sant. Graphene-based nanomaterials for drug delivery and tissue engineering. J Control Release 173: 75-88 (2014)

Google Scholar

[275]

C Dai, H Lin, G Xu, Z Liu, R Wu, Y Chen. Biocompatible 2D titanium carbide (MXenes) composite nanosheets for pH-Responsive MRI-guided tumor hyperthermia. Chem Mater 29(20): 8637-8652 (2017)

Google Scholar

[276]

X L Zhang, Y Xu, X Zhang, H Wu, J B Shen, R Chen, Y Xiong, J Li, S Y Guo. Progress on the layer-by-layer assembly of multilayered polymer composites: Strategy, structural control and applications. Prog Polym Sci 89: 76-107 (2019)

Google Scholar

[277]

X Q Yu, W S Zhang, P P Zhang, Z Q Su. Fabrication technologies and sensing applications of graphene-based composite films: Advances and challenges. Biosens Bioelectron 89: 72-84 (2017)

Google Scholar

[278]

J Yang, W Z Bao, P Jaumaux, S T Zhang, C Y Wang, G X Wang. MXene-based composites: Synthesis and applications in rechargeable batteries and superca-pacitors. Adv Mater Interfaces 6(8): 1802004 (2019)

Google Scholar

[279]

Z S Wu, Z Y Liu, K Parvez, X L Feng, K Müllen. Ultrathin printable graphene supercapacitors with AC line-filtering performance. Adv Mater 27(24): 3669- 3675 (2015)

Google Scholar

[280]

Z Ling, C E Ren, M Q Zhao, J Yang, J M Giammarco, J S Qiu, M W Barsoum, Y Gogotsi. Flexible and conductive MXene films and nanocomposites with high capacitance. Proc Natl Acad Sci USA 111(47): 16676-16681 (2014)

Google Scholar

[281]

P W Liu, A L Cottrill, D Kozawa, V B Koman, D Parviz, A T Liu, J F Yang, T Q Tran, M H Wong, S Wang, et al. Emerging trends in 2D nanotechnology that are redefining our understanding of “Nanocomposites”. Nano Today 21: 18-40 (2018)

Google Scholar

[282]

W Wang, G X Xie, J B Luo. Superlubricity of black phosphorus as lubricant additive. ACS Appl Mater Inter 10(49): 43203-43210 (2018)

Google Scholar

Friction

Volume 8 Issue 5,
October 2020

Pages 813-846

DOI: 10.1007/s40544-020-0401-4

Cite this article:

JI Z, ZHANG L, XIE G, et al. Mechanical and tribological properties of nanocomposites incorporated with two-dimensional materials. Friction, 2020, 8(5): 813-846. https://doi.org/10.1007/s40544-020-0401-4

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Received: 29 November 2019

Revised: 20 March 2020

Accepted: 07 May 2020

Published: 11 June 2020

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