Bottlebrush block copolymers offer unique advantages for polymer-nanoparticle assembly, arising from the stiffness of their backbones and the compositional tunability afforded by the lengths of the grafts in each block independently. The morphologies of ultrathin bottlebrush block copolymer films are extremely sensitive to the chemistry of the substrate. Modifying the substrate with a polymer brush that corresponds to one of the blocks of the bottlebrush copolymer leads to different, often non-bulk morphologies that relate to the interaction of the copolymer with the substrate, which is dictated by the bottlebrush polymer composition. In this work, we investigate the assembly of bottlebrush block copolymers of different compositions with gold nanoparticles, which are modified with polymeric ligands that correspond to one of the blocks. Our results show that the net interaction of the copolymer with the substrate influences the self-assembly process, leading to two types of routes: the co-assembly route, in which the nanoparticles are organized by the polymer into periodic structures, or macrophase separation. In the co-assembly route, selective substrates slightly distort the shape of the domains. The nanoparticles, in turn, influence the kinetics of the process by their interaction with the substrate.

Ultraconfined block copolymer films present non-bulk structures that are highly sensitive to film thickness and are strongly influenced by the wetting properties of the substrate. Here we describe the self-assembly of bottlebrush block copolymers with varying side-chain lengths on different types of substrates. Our results show a pronounced influence of the nature of the substrate on the self-assembled morphology and the surface patterns that evolve during solvent-vapor annealing. In particular, we observe by experiments and simulations a transient, substrate-driven morphology of cylinder-like structures obtained in films of doubly symmetric (i.e., backbone and side-chains) bottlebrush block copolymer despite the general tendency of these polymers to form lamellar structures. The insights gained from this study highlight the ability to use the substrate chemistry for inducing the formation of unique morphologies in bottlebrush block copolymer films.

Arrays of alternating metallic nanostructures present hybrid properties, which are useful for applications in photonics and catalysis. Block copolymer films provide versatile templates for fabricating periodic arrays of nanowires. Yet, creating arrays with alternating compositions or structures requires different modifications of domains of the same kind. By controlling the penetration depth of metal precursors into the film we were able to impregnate different layers of copolymer cylinders with different metals. Capitalizing on the hexagonal packing of the cylinders led to simultaneous formation of nanowires with alternating compositions and periodic arrangement on the substrate after plasma etching. Selective deposition of nanoparticles on the film enabled creating alternating bare and decorated nanowires, as well as trimetallic nanowire arrays.