posted on 2020-05-11, 17:47authored byZhengyuan Shen, Jingyi L. Chen, Viktoriia Vernadskaia, S. Piril Ertem, Mahesh K. Mahanthappa, Marc A. Hillmyer, Theresa M. Reineke, Timothy P. Lodge, J. Ilja Siepmann
Using
molecular dynamics simulations and transferable force fields,
we designed a series of symmetric triblock amphiphiles (or high-χ
block oligomers) comprising incompatible sugar-based (A) and hydrocarbon
(B) blocks that can self-assemble into ordered nanostructures with
sub-1 nm domains and full domain pitches as small as 1.2 nm. Depending
on the chain length and block sequence, the ordered morphologies include
lamellae, perforated lamellae, and hexagonally perforated lamellae.
The self-assembly of these amphiphiles bears some similarities, but
also some differences, to those formed by symmetric triblock polymers.
In lamellae formed by ABA amphiphiles, the fraction of B blocks “bridging”
adjacent polar domains is nearly unity, much higher than that found
for symmetric triblock polymers, and the bridging molecules adopt
elongated conformations. In contrast, “looping” conformations
are prevalent for A blocks of BAB amphiphiles. Above the order–disorder
transition temperature, the disordered states are locally well-segregated
yet the B blocks of ABA amphiphiles are significantly less stretched
than in the lamellar phases. Analysis of both hydrogen-bonded and
nonpolar clusters reveals the bicontinuous nature of these network
phases. This simulation study furnishes detailed insights into structure–property
relationships for mesophase formation on the 1 nm length scale that
will aid further miniaturization for numerous applications.