posted on 2025-01-11, 02:45authored bySemih Cetindag, Beatrice Bellini, Ruipeng Li, Esther H.R. Tsai, Dmytro Nykypanchuk, Gregory S. Doerk
With their ability to self-assemble spontaneously into
well-defined
nanoscale morphologies, block copolymer (BCP) thin films are a versatile
platform to fabricate functional nanomaterials. An important challenge
to wider deployment of BCPs in nanofabrication is combining precise
control over the nanoscale domain orientation in BCP assemblies with
scalable deposition techniques that are applicable to large-area,
curved, and flexible substrates. Here, we show that spray-deposited
smooth films of a nominally disordered BCP exhibit latent orientations,
which can be prescriptively selected by controlling solvent evaporation
during spray casting. Subsequent solvent vapor annealing triggers
assembly toward highly ordered cylindrical morphologies along the
pathway determined by solvent evaporation in the prior spray deposition
stage. Faster evaporation promotes assembly of vertically oriented
cylinders spanning the entire film thickness (100–300 nm).
In comparison, slow solvent evaporation permits intermicellar aggregation
and incipient cylinder formation in solution, which induces horizontal
cylinder assembly upon annealing. The evaporatively controlled latent
orientation mechanism presented herein elucidates how nonequilibrium
phenomena during casting govern successive self-assembly pathways
and facilitates a versatile method to dictate the domain orientation
of BCP thin films on demand on flexible and highly curved substrates
or in distinct pattern areas on the same substrate.