We examine the self-assembly of H-shaped block-copolymers as the function of the middle block to branch length
ratio and interaction between the middle and branch blocks differing in their solvophobicity. The work shows
that the examined H-shaped polymers readily transition from uniform mixing of the polymer species to domain
formation and a variety of advanced assembly configurations including vesicles, onion-like, and multi compartment aggregates. We identify the polymer conformational and packing changes involved to extract
governing interactions and molecule features giving rise to the different assembly structures. The findings are
discussed in terms of the H-shaped polymer architecture and polymer assemblies. We conclude that the assembly
structure is governed by the molecular level local curvature induced by the varying conformations of the
polymers. The findings highlight that for H-shaped polymers the degree of polymerization and polymer chem istries in terms of solvation and mixing characteristics of the blocks are keys to controlling the assembling
structures.