Effect of graphene on mechanical properties of cement mortars

Ming-li Cao; Hui-xia Zhang; Cong Zhang

doi:10.1007/s11771-016-3139-4

Journal of Central South University ›› 2016, Vol. 23 ›› Issue (4) : 919 -925. DOI: 10.1007/s11771-016-3139-4

Geological, Civil, Energy and Traffic Engineering

Effect of graphene on mechanical properties of cement mortars

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Abstract

Functionalized graphene nano-sheets (FGN) of 0.01%−0.05% (mass fraction) were added to produce FGN-cement composites in the form of mortars. Flow properties, mechanical properties and microstructure of the cementitious material were then investigated. The results indicate that the addition of FGN decreases the fluidity slightly and improves mechanical properties of cement-based composites significantly. The highest strength is obtained with FGN content of 0.02% where the flexural strength and compressive strength at 28 days are 12.917 MPa and 52.42 MPa, respectively. Besides, scanning electron micrographs show that FGN can regulate formation of massive compact cross-linking structures and thermo gravimetric analysis indicates that FGN can accelerate the hydration reaction to increase the function of the composite effectively.

Keywords

functionalized graphene nano-sheets / cement mortars / mechanical strength / microstructure

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Ming-li Cao, Hui-xia Zhang, Cong Zhang. Effect of graphene on mechanical properties of cement mortars. Journal of Central South University, 2016, 23(4): 919-925 DOI:10.1007/s11771-016-3139-4

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]

HoustY F, BowenP, PercheF, KauppiA, BorgetP, GalmichecL, MeinscJ F L, LafumacF, FlattdR J, SchoberdI, BanfilleP F G, SwifteD S, MyrvoldfB O, PetersenfB G, ReknesfK. Design and function of novel superplasticizers for more durable high performance concrete (Superplast Project)[J]. Cement and Concrete Research, 2008, 38(10): 1197-1209

[2]	van TittelboomK, de BelieN, LehmannF, GrosseC U. Acoustic emission analysis for the quantification of autonomous crack healing in concrete [J]. Construction and building Materials, 2012, 28(1): 333-341

[3]	BenteD P. Influence of silica fume on diffusivity in cement based materials II: Multi-scale modeling of concrete diffusivity [J]. Cement and Concrete Research, 2000, 30: 1121-1129

[4]	BischoffP H. Tension stiffening and cracking of steel fiber-reinforced concrete [J]. Journal of Materials in Civil Engineering, 2003, 15(2): 174-182

[5]	LawlerJ S, ZampiniD, ShahS P. Microfiber and macrofiber hybrid fiber reinforced concrete [J]. J Mater Civ Eng, 2005, 17: 595

[6]	LuC-h, CuiZ-w, LiuR-g, LiuQ-dong. Chloride diffusivity in flexural cracked Portland cement concrete and fly ash concrete beams [J]. Journal of Central South University, 2014, 21: 3682-3691

[7]	ToumeyC P. Rea DING Feynman into nanotechnology [J]. Techné: Research in Philosophy and Technology, 2008, 12(3): 133-168

[8]	DrexlerK E. Nanotechnology: From Feynman to fun DING [J]. Bulletin of Science, Technology & Society, 2004, 24(1): 21-27

[9]	LiG-y, WangP-m, ZhaoX-hua. Mechanical behavior and microstructure of cement composites incorporating surface-treated multi-walled carbon nanotubes [J]. Carbon, 2005, 43(6): 1239-1245

[10]	LiY-h, WangS-g, WeiJ-q, ZhangX-f, XuC-l L Z-k, WuD-h W B-qing. Lead adsorption on carbon nanotubes [J]. Chemical Physics Letters, 2002, 357(3): 263-266

[11]	MahmoudM E, AlbishriH M. Supported hydrophobic ionic liquid on nano-silica for adsorption of lead [J]. Chemical Engineering Journal, 2011, 166(1): 157-167

[12]	ShihJ, ChangT, HsiaoT. Effect of nanosilica on characterization of Portland cement composite [J]. Materials Science and Engineering A, 2006, 424(1): 266-274

[13]	RaoM-m, SongX-y, CairnsE J. Nano-carbon/sulfur composite cathode materials with carbon nanofiber as electrical conductor for advanced secondary lithium/sulfur cells [J]. Journal of Power Sources, 2012, 205: 474-478

[14]	MetaxaZ S, Konsta-GdoutosM S, ShahS P. Carbon nanofiber-reinforced cement-based materials [J]. Transportation Research Record: Journal of the Transportation Research Board, 2010, 2142(1): 114-118

[15]	KordásK, MustonenT, TóthG, JantunenH, LajunenM, SoldanoC, TalapatraS, VajtaiR, AjayanP. Inkjet printing of electrically conductive patterns of carbon nanotubes [J]. Small, 2006, 2(8/9): 1021-1025

[16]	GeimA K, NovoselovK S. The rise of graphene [J]. Nature Materials, 2007, 6(3): 183-191

[17]	LeeC, WeiX-d, KysarJ W, HoneJ. Measurement of the elastic properties and intrinsic strength of monolayer graphene [J]. Science, 2008, 321(5887): 385-388

[18]	PangH, ChenT, ZhangG-m Z B-q, LiZ-ming. An electrically conducting polymer/graphene composite with a very low percolation threshold [J]. Materials Letters, 2010, 64(20): 2226-2229

[19]	BlanterY M, MartinI. Transport through normal-metal–graphene contacts [J]. Physical Review B, 2007, 76(15): 155433

[20]	WalkerL S, MarottoV R, RafieeM A, CorralE L. Toughening in graphene ceramic composites [J]. Acs Nano, 2011, 5(4): 3182-3190

[21]	AlkhatebH, AlostsazA, ChengA H, LiX-bing. Materials genome for graphene-cement nanocomposites [J]. Journal of Nanomechanics and Micromechanics, 2013, 3(3): 67-77

[22]	LvS-h, MaY-j, QiuC-c, JuH-bo. Effects of graphene oxide on microstructure of hardened cement paste and its properties [J]. Concrete, 2013, 8: 51-54

[23]	LvS-h, SunT, LiuJ-j, MaY-j, QiuC-chao. Toughening effect and mechanism of graphene oxide nanosheets on cement matrix composites [J]. Acta Materiae Compositae Sinica, 2014, 3: 644-652

[24]	RoscaI D, WatariF, UoM, AkasakaT. Oxidation of multiwalled carbon nanotubes by nitric acid [J]. Carbon, 2005, 43(15): 3124-3131

[25]	EnN FMethods of test for cements-Part I: Determination of mechanical resistance [S], 2006

[26]	LiH, XiaoH-g, YuanJ, OuJ-ping. Microstructure of cement mortar with nano-particles [J]. Composites Part B: Engineering, 2004, 35(2): 185-189

[27]	NazariA, RiahiS, RiahiS, ShamekhiaF, KhademnoA. Mechanical properties of cement mortar with Al₂O₃ nanoparticles [J]. Journal of American Science, 2010, 6(4): 94-97

[28]	CwirzenA, HabermehlcK, PenttalaV. Surface decoration of carbon nanotubes and mechanical properties of cement/carbon nanotube composites [J]. Advances in Cement Research, 2008, 20(2): 65-73

[29]	LvS-h, MaY-j, QiuC-c, ZhouQ-fang. Regulation of GO on cement hydration crystals and its toughening effect [J]. Magazine of Concrete Research, 2013, 65(19/20): 1246-1254

[30]	AlkhatebH, AlostazA, ChengA H, LiX-bing. Materials genome for graphene-cement nanocomposites [J]. Journal of Nanomechanics and Micromechanics, 2013, 3(3): 67-77

[31]	LvS-h, MaY-j, QiuC-c, SunT, LiuJ-j, ZhouQ-fang. Effect of graphene oxide nanosheets of microstructure and mechanical properties of cement composites [J]. Construction and building Materials, 2013, 49: 121-127

[32]	DweckJ, FerreiraD S, BüchlerP M, CartledgeF. Study by thermogravimetry of the evolution of ettringite phase during type II Portland cement hydration [J]. Journal of Thermal Analysis and Calorimetry, 2002, 69(1): 179-186