A systematic approach of using poly(oxyalkylene)-amine-salt terminated 2,2-bis(4-hydroxyphenyl)propane. epoxy oligomers for modifying the layered silicate clays has led to organoclays with different surfactant properties. The pristine layered structure of natural clays such as sodium montmorillonite (Na+-MMT) could be organically intercalated into basal spacing from 12Å to 100Å and exfoliated to form randomized thin layer silicate platelets (ca. 1 nm thickness) , depending on the choices of the amine-oligomers. The organic modification of the ionic clays with cation exchanged capacity of 120 mequiv./100g involved the amine-salt ionic exchange reaction and accompanied by the organic incorporation into the clay layered structure as the first step. These organoclays were characterized by X-ray diffraction and shown their expanded basal spacing up to 100 Å and even into randomized platelets, and confirmed by TEM examination. Furthermore, we manipulated the organoclays fraction of hydrophobic amine-oligomers and hydrophilic randomized thin layer silicate platelets by reverse ion exchanged reaction as the second step. The cooperation of organic amine-oligomers and inorganic platelets has led to amphiphilic property in balanced organic fraction. The amphiphilic nature was further enhanced by their ability of lowering the surface tension at the water–air interface from 72 to 41 mN/m at 1 wt% of organoclay. The platelet ionic charges were analyzed by zeta potential measurement showing a pH-dependent charge species existed on the surface of the random platelets. The zeta potential of balanced organoclay was demonstrated charge reverse with pH changed, showing the interaction of nano silicate platelets and amine-oligomers can be evidenced. Since the amphiphilic organoclay synthesized, extremely stable emulsions form even the clay–amine suspension remains unflocculated in water/toluene biphase and assisted pigment dispersion. Moreover, amphiphilic organoclay with magnetic iron-oxide nanoparticles (FeNPs) embedded in the clay were synthesized by in situ Fe2+/Fe3+ coprecipitation. Then pigment adsorption with magnetic force in water was carried on. On the other side, as the filler, good enhancement of epoxy nanocomposites was carried, not only mechanical but also thermal property, raising pencil hardness from 2H to 4H with only 0.5 wt%. The high aspect-ratio and fine dispersion of the platelet silicates were found to be important factors in influencing the cured epoxy.