swollen sample was wholly evaporate

swollen sample was wholly evaporated within 1 day. We
selected the drying condition of 70 C and 1 day. Fig. 1
shows the wax solubilities (Swax) of the unfilled and filled
NR, SBR, and BR vulcanizates. The Swaxs of the unfilled
samples were much higher than those of the filled ones.
The Swaxs of the NR vulcanizates were higher than those of
the SBR and BR ones, irrespective of the filler systems. This
can be explained by the solubility parameters. A rubber
having a similar solubility parameter to wax can have
higher wax solubility because compatibility between two
materials increases as the difference in the solubility
parameters decreases. Solubility parameters of NR, SBR
(styrene content 23.5 wt%), and BR are 8.10, about 8.32, and
8.44 cal1/2 cm3/2, respectively [14]. Solubility parameters
of waxes may be about 8.0 cal1/2 cm3/2 because those of
n-hexane and n-decane are 7.42 and 7.90 cal1/2 cm3/2,
respectively [14]. Thus, NR has larger wax solubility than
SBR and BR. For unfilled SBR and BR vulcanizates, the Swax
of the SBR specimen was lower than that of the BR sample.
This cannot be explained by the solubility parameter.
However, the Swaxs of the filled SBR vulcanizates were
higher than those of the BR ones.
For measurement of wax solubility with the wax solution
in toluene, the Swax must be affected by the solvent
swelling ratio. The swelling ratio was obtained by the
equation of Q ¼ (Wtoluene  Wsample)/Wsample, where the
Wtoluene and Wsample are the weights of the toluene-swollen
sample and the organic materials-extracted sample,
respectively. The 1/Q is used as the apparent crosslink
density [15–18]. Fig. 2 shows the toluene swelling ratios of
the unfilled and filled specimens. The Q values of the
unfilled samples were much higher than those of the filled
ones. For the unfilled specimens, the order of the Q value
was SBR > NR > BR. The Q values of the unfilled NR, SBR,
and BR were 4.37, 4.56, and 4.32, respectively. The Q values
of the carbon black-filled specimens were lower than those
of the silica-filled ones, irrespective of the kind of rubber.
This is because of the adsorption of curatives on the silica
surface [19–21]. The curatives adsorption leads to
a decrease in crosslink density and an increase in solvent
swell. For the carbon black-filled rubber composites, the
swelling ratios of the NR and SBR specimens were higher
than that of BR. Fig. 3 shows the wax solubilities corrected
by the solvent swelling ratio. The solvent swell-corrected
wax solubility (Swaxswell) was obtained by dividing Swax by
the Q value. The Swaxswells of the unfilled samples were still
higher than those of filled ones. For the unfilled specimens,
the order of the Swaxswell was the same with the Swax:
NR > BR > SBR. For the filled specimens, the Swaxswells of the
filled NR composites were higher than those of the SBR and
BR ones. This can be also explained by the solubility
parameters as discussed above.
During mixing, filler particles are distributed and
dispersed in the rubber matrix. Some rubber chains are
attached to the fillers so bound rubber is formed [22–25].
Properties of the bound rubber depend on the characteristics
of the filler such as the surface area, structure or
morphology and surface activity. In addition, the filler–
polymer interactions also lead to the formation of bound
rubber by the physical adsorption, chemisorption and
mechanical interaction. Most filler particles may be