Polyurethanes represent extraordinarily versatile polymeric materials which can be tailored to meet the highly diversified demands of modern technologies such as coatings, adhesives, reaction injection molding, fibers, foams, rubbers, thermoplastic elastomers, and composites. [1±3] It is an important objective in polyurethane development to improve resistance against mechanical deformation without sacrificing high elongation at break. Since the early pioneering advances by Otto Bayer, [4] polyurethane properties are modified either by varying polyurethane microstructure, resulting from step-growth polymerization of isocyanate resins with polyols, or by dispersing inorganic and organic fillers within the polyurethane continuous matrix. A wide variety of fillers, including clay and wollastonites, are being applied in polyurethane formulations to reduce costs and to reinforce the polyurethane matrix. [5] Properties of filled polyurethanes are dependent upon filler shape, average diameter and interfacial coupling. Anisotropic particles with a large length/diameter ratio (aspect ratio), e.g., whiskers and fibers, were found to be especially effective in matrix reinforcement. Frequently, filler addition is accompanied by increased strength and stiffness at the expense of substantially reduced elongation at break.Although nanoscale anisotropic particles are expected to offer attractive potential for polyurethane reinforcement, application of anisotropic nanofillers is restricted by the limited availability of nanowhiskers, poor dispersion, and handling problems associated with potential health hazards resulting from inhalation of such particles. Therefore, several attempts have been made to produce nanowhisker dispersions in polyols which are much easier to handle. For example, N-(4-aminobenzoyl)-caprolactam was polymerized at 200 C in dihydroxy-terminated poly(tetrahydrofuran) to produce dispersions of rigid polybenzamide nanowhisker of approximately 2000 nm length and 200 nm diameter. Interfacial coupling and steric stabilization were achieved by reacting hydroxy end groups of the polyol with N-acyl-lactam end groups located at the polybenzamide whisker surface. Upon curing with diisocyanate, the resulting polyurethane nanocomposites exhibited the unusual combination of increased tensile strength and Young's modulus without sacrificing high elongation at break. [6,7] Particle formation via sol/gel technology leads to dispersions of mainly isotropic nanoparticles in polyurethane. [8] Recently, intercalation of organophilic layered silicates with polymers has been introduced as an attractive route leading to versatile polymer nanocomposites which contain nanoscale layered silicates with high aspect ratio. Layered silicates, e.g., clay, consist of anionically charged layers of aluminum/magnesium or magnesium/lithium silicates where cations such as sodium, potassium, magnesium or calcium are located in the interlayer galleries. They are rendered organophilic when gallery cations are exchanged by quaternary alkyl ammonium...
