Abstract
Molecular dynamics simulations are used to investigate the phase behavior of asymmetric AB(1)B(2)-type miktoarm triblock amphiphiles, composed of a sugar-based acyclic headgroup (A) and two hydrocarbon tails (B(1) and B(2)). AB(1)B(2) amphiphiles with significantly shorter B(2) tails (f (B(1)) /F (B(2)) ≫ 1, where f (i) is the volume fraction) form lamellar (LAM) and perforated lamellae (PL) structures, whereas those with nearly equal tail lengths (f (B(2)) ≈ F (B(1)) ) assemble into hexagonally packed cylinders (CYL). Amphiphiles with a B(1)/B(2) length ratio near 2:1 (2f (B(2)) ≈ F (B(1)) ) stabilize double gyroid (DG) networks, where the headgroups form the interconnected channels and the tails constitute the matrix, displaying feature sizes from 1.7 to 3.3 nm across a broad volume fraction range with 0.22 ≤ fA ≤ 0.40 . For potential applications in membrane separation at infinite dilution, these networks significantly hinder the diffusion of polar molecules, while nonpolar molecules diffuse relatively unimpeded. Diffusion selectivities near 3 are found for 1-butanol versus water and n-hexane versus methanol. Self-consistent field theory (SCFT) calculations corroborate the presence of DG networks at intermediate compositions for AB(1)B(2) miktoarm triblock polymers, although no specific B(1)/B(2) ratio is predicted to significantly broaden the network phase window. This study highlights the role of asymmetry in the molecular design of amphiphilic block oligomers, which enables the stabilization of network morphologies with ultrasmall feature sizes over a wide composition range.