Binary Blends of Diblock Copolymers: An Efficient Route to Complex Spherical Packing Phases

Abstract

The phase behaviour of binary blends composed of A1B1 and A2B2 diblock copolymers is systematically studied using the polymeric self-consistent field theory, focusing on the formation and relative stability of various spherical packing phases. The results are summarized in a set of phase diagrams covering a large phase space of the system. Besides the commonly observed body-centered-cubic (BCC) phase, complex spherical packing phases including the Frank-Kasper A15 and σ and the Laves C14 and C15 phases could be stabilized by the addition of longer A2B2-copolymers to asymmetric A1B1-copolymers. Stabilizing the complex spherical packing phases requires that the added A2B2-copolymers have a longer A-block and an overall chain length at least comparable to the host copolymer chains. A detailed analysis of the block distributions reveals the existence of inter- and intra-domain segregation of different copolymers, which depends sensitively on the copolymer length ratio and composition. The predicted phase behaviours of the A1B1/A2B2 diblock copolymer blends are in good agreement with available experimental and theoretical results. The study demonstrated that binary blends of diblock copolymers provide an efficient route to regulate the emergence and stability of complex spherical packing phases.