Litcius/Paper detail

Discrete Linear–Branched Block Copolymer with Broken Architectural Symmetry

Zhuang Ma, Dongdong Zhou, Miao Xu, Zhanhui Gan, Tianyu Zheng, Shuai Wang, Rui Tan, Xue‐Hui Dong

2023Macromolecules25 citationsDOI

Abstract

Rationally introducing chain length heterogeneity, such as binary blending, is a robust approach to regulate phase behavior of block copolymers. This work designed a library of discrete linear–branched block copolymers bearing two unequal branches. Diverse ordered nanostructures, including complex Frank–Kasper phases and quasicrystalline phase, were captured by tuning the compositional and architectural asymmetry. The precise chemistry rules out the interferences associated with statistical distribution, while the discrete feature decouples the intertwined variables. Compared with the symmetric counterparts, the synergies between the long and short chains effectively release the packing frustration during the formation of ordered structures, leading to a significant increase of lattice dimension and phase stability. The “built-in” chain length heterogeneity circumvents the shortcomings encountered by the conventional blending strategy, providing an excellent alternative for quantitatively assessing the effect of molecular symmetry on the self-assembly behaviors of block copolymers.

Topics & Concepts

CopolymerAsymmetrySymmetry (geometry)Binary numberStatistical physicsLattice (music)Block (permutation group theory)FrustrationMaterials scienceSelf-assemblyPhase (matter)Chemical physicsPolymer scienceComputer sciencePolymer chemistryNanotechnologyMathematicsChemistryPhysicsCombinatoricsCondensed matter physicsGeometryPolymerComposite materialArithmeticQuantum mechanicsOrganic chemistryAcousticsBlock Copolymer Self-AssemblyAdvanced Polymer Synthesis and CharacterizationMachine Learning in Materials Science