We report the synthesis and morphological characterization of two trib
lock copolymers of the ABA type, where A is polystyrene (PS) and B pol
yisoprene (PI). The volume fraction of the minority component, PS or P
I, is approximately 1/3. Cubic microdomain morphologies, already found
in diblock and star block copolymers with the same composition range,
are observed for the first time in the case of linear triblock copoly
mers. The two ABA triblocks are on opposite sides of the phase diagram
, which signifies that both the A end blocks and the B midblock are ca
pable of forming the interconnected double network structure. Investig
ation of the morphology was done via birefringence, small-angle X-ray
scattering (SAXS), and transmission electron microscopy(TEM). Birefrin
gence measurements showed each triblock structure to have isotropic op
tical properties. The characteristic ratio of the observed Bragg peaks
, q(2)/q(1), was approximately root 4/root 3 for each sample, indicati
ng a set of eight possible cubic space groups. TEM data showed an inte
rconnected tricontinuous microdomain structure. Since the two triblock
s have essentially complementary structures (PS = 0.32 in one and PI =
0.36 in the other), the TEM images of OsO4-stained thin sections are
complementary and the diffraction patterns of the images are approxima
tely equal according to Babinet's principle. Examination of high-symme
try projections demonstrated p6mm, p4mm, and c2mm symmetry present in
the TEM images. Comparison with the [111], [100], and [100] projection
s of the eight cubic space groups satisfying the SAXS data eliminated
all but the <Fm(3)over bar m> and <Ia(3)over bar d> groups as possible
structures. Due to the observed connectivity of the structure, the <F
m(3)over bar m> structure could be eliminated by inspection of possibl
e network structures and the resultant symmetries. Computer simulation
s of a model structure (double gyroid) based on level surfaces with <I
a(3)over bar d> symmetry and their Fourier transforms showed excellent
agreement with the high-symmetry projections and their respective opt
ical transforms.