Reinforcing materials such as carbo

Reinforcing materials such as carbon black (CB) and silica are used extensively, in the rubber industries, to improve tensile properties, tear and abrasion resistance, and hardness of a rubber vulcanizate. Recently researchers have tried to replace these materials with nanoparticles such as nano-clay, nano-silica and carbon nanotube. The properties of nanocomposites depend greatly on the chemistry of polymer matrices, nature of nanofillers, and the method in which they are prepared. Developments in the field of elastomer nanocomposites reinforced with layered silicates, silica, carbon nanotubes, nanofibers and various other nanoparticles have been reported by Maiti et al. (2008). Clay is “a naturally occurring material composed primarily of fine-grained minerals, which is generally plastic at appropriate water contents and will harden when dried or fired.” Therefore, natural clay will consist of a/several clay minerals mixed with additional minerals as impurities (Bergaya et al., 2011 and Bergaya and Lagaly, 2013). Clay mineral particle is composed of many mono-layers with 1 nm thickness. The presence of cations in the interlayer space of the clay mineral makes it hydrophilic in nature. Modification of clay minerals with organic cationic surfactant renders the clay mineral hydrophobic at the surface and improves its compatibility with the organic molecules. This modification also expands the interlayer space of the clay mineral (Pavlidou and Papaspyrides, 2008).

It is known that the use of organo-modified clay (OC) in a polymer has a considerable influence on the improvement of its properties such as mechanical (Lopez-Manchado et al., 2003, Jia et al., 2008, Carli et al., 2011, Monfared et al., 2014 and Shoushtari Zade Naseri and Jalali-Arani, 2015) thermal stability (Denardin et al., 2001 and Wang et al., 2006;), gas permeability resistance (Teh et al., 2004a and Choudalakis and Gotsis, 2009) and flame retardancy (Zhang et al., 2005 and Liu et al., 2009) properties. In this regard preparation of clay polymer nanocomposites (CPNs) based on natural rubber (NR) has been reported (Bokobza and Rapoport, 2002, Lopez-Manchado et al., 2003, Teh et al., 2004a, Teh et al., 2004b, Jacob et al., 2007, Bhattacharya et al., 2008, Liu et al., 2009 and Nematollahi et al., 2014). However the layered silicates existing in nanoscale dimensions can improve the rubber material properties but the homogeneous dispersion of individual silicate layers in a rubber matrix, especially by means of a conventional rubber-compounding process, is difficult (Zheng et al., 2004). For preparation of elastomeric nanocomposites, some of the researchers recently have paid more attention to the use of organoclay (OC) in combination with other nanostructured fillers such as CB (Maiti et al., 2005, Herrmann et al., 2006, Praveen et al., 2009, Rattanasom and Prasertsri, 2009, Basuli and Chattopadhyay, 2010, Chattopadhyay and Basuli, 2010, Praveen et al., 2010, Gopi et al., 2011, Galimberti et al., 2012 and Annadurai et al., 2014), silica (Kim et al., 2013 and Bao et al., 2015) and nano-calcium carbonate (nano-CaCO3) (Zare et al., 2011 and Sadeghi Ghari et al., 2013). The synergistic effect of OC and CB in the NR was also reported (Rattanasom and Prasertsri, 2009 and Qu et al., 2010). Qu et al. (2010) reported marked enhancement in tensile strength from 11.4 MPa for neat NR to 28.2 MPa for NR nanocomposite with 5 wt.% nanoclay and 20 wt.% CB and explained that the crystallization plays a less important role in the reinforcement of nanoclay/CB NR. Galimberti et al., 2012 and Galimberti et al., 2013 used montmorillonite (Mt), modified with an organophilic ammonium as the compensating cation (OMt), and CB in poly-(1, 4-cis-isoprene) (PI) and studied the morphology, as well as the static and dynamic mechanical behavior of the CPN. They found that OMt in the presence of CB, promoted a higher enhancement of the initial modulus and mechanical reinforcement. In these works the interaction between the organophilic ammonium cation and CB was reported as the origin of the synergism between OMt and CB.

The effects of simultaneous use of CB and OC on improvement of mechanical properties of styrene butadiene rubber (SBR) (Praveen et al., 2009), hydrogenated acrylonitrile-butadiene rubber (HNBR) (Herrmann et al., 2006), polyurethane and brominated isoprene isobutylene rubber (BIIR) (Praveen et al., 2010) were reported. The use of OC in combination with polymeric nanoparticles was also studied. For instance Rezaei Abadchi and Jalali-Arani (2015) used OC and polybutadiene rubber powder (PBRP) nanoparticles in polypropylene (PP) and investigated the effect of PBRP on morphology and mechanical properties of the sample.

NR is a high molecular mass polymeric substance which exhibits high tensile strength as a gum vulcanizate. It can be considered as one of the most important polymers and is widely used in the rubber industries. In this work (OC/nano-CaCO3/NR) nanocomposites were prepared by melt mixing method and the effect of OC in the presence of nano-CaCO3 on the morphology, mechanical properties and swelling resistance of the NR was investigated by the experimental tests. In addition, theoretical investigation was employed to discuss the obtained results.