Epoxy polymers, although often used in fiber-reinforced polymeric composites, have an inherent low toughness that further decreases with decreasing temperatures. Second-phase additives have been effective in increasing the toughness of epoxies at room temperature; however, the mechanisms at low temperatures are still not understood. In this study, the deformation mechanisms of a diglycidyl ether of bisphenol-A epoxy modified with MX960 core-shell rubber particles were investigated under quasi-static tensile and impact loads at room temperature and liquid nitrogen temperature. Overall, the core-shell rubber had little effect on the tensile properties at room temperature and liquid nitrogen temperature. The impact strength decreased from neat to 1 wt% and 3 wt% but increased from neat to 5 wt% at room temperature and liquid nitrogen temperature, with a higher impact strength at room temperature at all core-shell rubber loadings. While a large toughening effect was not seen in this study, the mechanisms analyzed herein will likely be of use for further material investigations at cryogenic temperatures.
AskelandDRPhulePP. The science and engineering of materials, Pacific Grove: Brooke/Cole, Thompson Learning, 2003.
2.
PearsonRAYeeAF. Toughening mechanisms in thermoplastic-modified epoxies: 1. Modification using poly(pohenylene oxide). Polymer1993; 34(17): 3658–3670.
3.
Delay T, Patterson J, Schneider JA, et al. Development of composite overwrapped pressure vessels for high pressure cryogenic storage applications. In: SAMPE Conference, Long Beach, CA, 30 April–4 May 2006.
4.
Hastings WC. Cryogenic temperature effects on the mechanical properties of carbon, aramid, and PBO fibers. MS Thesis, Mississippi State University, Mississippi State, MS, USA, 2008.
PearsonRAYeeAF. Toughening mechanisms in elastomer-modified epoxies. Part 3: the effect of cross-link density. J Mater Sci1989; 24: 2571–2580.
7.
MeeksAC. Fracture and mechanical properties of epoxy resins and rubber-modified epoxy resins. Polymer1974; 15: 675–681.
8.
CherryBWThompsonKW. The fracture of highly crosslinked polymers. Part 1. Characterization and fracture toughness. J Mater Sci1981; 16: 1913–1924.
9.
ScottJMWellsGMPhillipsDC. Low temperature crack propagation in an epoxide resin. J Mater Sci1980; 15: 1436–1448.
10.
LiuJSueHJThompsonZJ. Effect of crosslink density on fracture behavior of model epoxies containing block copolymer nanoparticles. Polymer2009; 50(19): 4683–4689.
OrmaetxeaMForcadaJMugikaF. Ultimate properties of rubber and core-shell modified epoxy matrices with different chain flexibilities. J Mater Sci2001; 36: 845–852.
13.
LinKFShiehYD. Core-shell particles designed for toughening the epoxy resins. II. Core-shell-particle-toughened epoxy resins. J Appl Polym Sci1998; 70: 2313–2322.
14.
MafiEREbrahimiM. Role of core-shell rubber particle cavitation resistance on toughenability of epoxide resins. Polym Eng Sci2008; 48(7): 1376–1380.
15.
DunkelbergerDLDoughertyEP. Effect of morphology and refractive index on toughness and clarity balance of MBS modified vinyl bottles. J Vinyl Technol1990; 12(4): 212–216.
16.
GiannakopoulosGMasaniaKTaylorAC. Toughening of epoxy using core-shell particles. J Mater Sci2011; 46: 327–338.
17.
RiewCKSiebertARSmithRW. Toughened plastics II – novel approaches in science and engineering1996; Vol. 252Advances in Chemistry Series. Washington DC: American Chemical Society.
18.
HsiehTHKinlochAJMasaniaK. The toughness of epoxy polymers and fibre composites modified with rubber microparticles and silica nanoparticles. J Mater Sci2010; 45: 1193–1210.
19.
HuangYGKinlochAJ. Modelling of the toughening mechanisms in rubber-modified epoxy polymers Part II. A quantitative description of the microstructure-property relationships. J Mater Sci1992; 27: 2763–2769.
20.
KinlochAJ. Rubber-toughened plastics1989; Vol. 222Advances in Chemistry Series. Washington DC: American Chemical Society.
21.
HuangCJFuSYZhangYH. Cryogenic properties of SiO2/epoxy nanocomposites. Cryogenics2005; 45: 450–454.
22.
Roulin-MoloneyAC. Fractography and failure mechanics of polymers and composites, London, UK: Elsevier Applied Science, 1989.
23.
BagheriRPearsonRA. Role of particle cavitation in rubber-toughened epoxies: 1. Microvoid toughening. Polymer1996; 37(20): 4529–4538.
24.
BucknallCBHeatherPSLazzeriA. Rubber toughening of plastics Part 12. Deformation mechanisms in toughened nylon 6,6. J Mater Sci1989; 16: 2255–2261.
25.
SueHJGarcia-MeitinJWOrchardNA. Toughening of epoxies via craze-like damage. J Polym Sci Part B: Polym Phys1993; 31: 595–608.
26.
Yee AF and Pearson RA. Toughening mechanisms in elastomer-modified epoxy resins – Part I. NASA Contractor Report, 1983.
27.
CorreaCAde SousaJA. Rubber particle size and cavitation process in high impact polystyrene blends. J Mater Sci1997; 32: 6539–6547.
28.
Becu-LonguetLBonnetAPichotC. Epoxy networks toughened by core-shell particles: Influence of the particle structure and size on the rheological and mechanical properties. J Appl Polym Sci1999; 72: 849–858.
29.
DompasDGroeninckxGIsogawaM. Cavitation debonding during deformation of rubber-modified poly(vinyl chloride). Polymer1995; 36(2): 437–441.
30.
PearsonRAYeeAF. Influence of particle size and particle size distribution on toughening mechanisms in rubber-modified epoxies. J Mater Sci1991; 26: 3828–3844.
31.
KimDSChoKKimJK. Effect of particle size and rubber content on fracture toughness in rubber-modified epoxies. Polym Eng Sci1996; 36(6): 755–768.
32.
BucknallCB. Blends containing core-shell impact modifiers Part 1. Structure and tensile deformation mechanisms. Pure Appl Chem2001; 73(6): 897–912.
33.
HuangYGKinlochAJ. The sequence of initiation of the toughening micromechanisms in rubber-modified epoxy polymers. Polymer1992; 33(24): 5338–5340.
34.
O'Hara GP. Mechanical properties of silicone rubber in a closed volume. US Army Armament Research & Development Center, Benet Weapons Laboratory, 1983.
35.
HuangYGHunstonDLKinlochAJ. Mechanisms of toughening thermoset resins. Toughened plastics I, Washington DC: American Chemical Society, 1993.
36.
KinlochAJShawSJTodDA. Deformation and fracture behavior of a rubber-toughened epoxy: 1. Microstructure and fracture studies. Polymer1983; 24: 1341–1354.
37.
BascomWDCottingtonRLJonesRL. The fracture of epoxy- and elastomer-modified epoxy polymers in bulk and as adhesives. J Appl Polym Sci1975; 19(9): 2545–2562.
38.
HuangYGKinlochAJ. The role of plastic void growth in the fracture of rubber-toughened epoxy polymers. J Mater Sci Lett1992; 11: 484–487.
39.
HuangYGKinlochAJ. Modelling of the toughening mechanisms in rubber-modified epoxy polymers Part 1. Finite element analysis studies. J Mater Sci1992; 27: 2753–2762.
40.
SueHJYeeAF. Deformation behaviour of a polycarbonate plate with a circular hole: finite elements model and experimental observations. Polymer1988; 29: 1619–1624.
41.
LangeFFRadfordKC. Fracture energy of an epoxy composite system. J Mater Sci1971; 6: 1197–1203.
42.
LangeFF. The interaction of a crack front with a second-phase dispersion. Philos Mag1970; 22: 983–992.
43.
BagheriRPearsonRA. Role of particle cavitation in rubber-toughened epoxies: II. Inter-particle distance. Polymer2000; 41: 269–276.
44.
Kunz-DouglassSBeaumontPWRAshbyM.F. A model for the toughness of epoxy-rubber particulate composites. J Mater Sci1980; 15: 1109–1123.
45.
EvansAGFaberKT. Crack-growth resistance of microcracking brittle materials. J Am Ceramic Soc1983; 67(4): 255–260.
46.
Jackson JR. Fracture toughness of polymer resins at cryogenic temperatures. MS Thesis, Mississippi State University, Mississippi State, MS, 2005.
47.
ASTM 2007. ASTM D5418 Standard test method for plastics: dynamic mechanical properties. In: Flexure (dual cantilever beam). West Conshohocken, PA: ASTM, 2007.
48.
ASTM 2005. ASTM D638 Standard test method for tensile properties of plastics, West Conshohocken, PA: ASTM, 2005.
49.
SII NanoTechnology Inc. Thermal analysis of silicone rubber, www.siint.com (1985, accessed 23 March 2011).
GreenJLPettyCAGillisPP. Relationship between strain rate, temperature, and impact failure mechanism for poly(vinyl chloride) and poly(ethylene terephthalate). Polym Eng Sci1998; 38: 194–203.
52.
SahraouiSLatailladeJL. Analysis of load oscillations in instrumented impact testing. Eng Fract Mech1998; 60: 437–446.
53.
MichlerGH. Electron microscopy of polymers, Berlin: Springer-Verlag, 2008.
54.
LuFCantwellWJKauschHH. The role of cavitation and debonding in the toughening of core-shell rubber modified epoxy systems. J Mater Sci1997; 32: 3055–3059.
55.
FiedlerBHojoMOchiaiS. Failure behavior of an epoxy matrix under different kinds of static loading. Compos Sci Technol2001; 61: 1615–1624.
BrownENWhiteSRSottosNR. Microcapsule induced toughening in a self-healing polymer composite. J Mater Sci2004; 39: 1703–1710.
60.
Van Der SandenMCMMeijerHEHLemstraPJ. Deformation and toughness of polymeric systems: 1. The concept of a critical thickness. Polymer1993; 34(10): 2148–2154.
61.
WuS. Phase structure and adhesion in polymer blends: a criterion for rubber toughening. Polymer1985; 28: 1855–1863.
62.
Chen ZK, Yang G, Yang JP, et al. Simultaneously increasing cryogenic strength, ductility and impact resistance of epoxy resins modified by n-butyl glycidyl ether. Polymer 2009; 50: 1316–1323.
