posted on 2017-02-21, 00:00authored byJyo Lyn Hor, Yijie Jiang, David J. Ring, Robert A. Riggleman, Kevin T. Turner, Daeyeon Lee
In
this work, we present the fabrication of nanoporous polymer-infiltrated
nanoparticle films (PINFs) with either uniform or graded porosity
based on undersaturated capillary rise infiltration (UCaRI) and study
the processing-structure–property relationship of these nanoporous
PINFs. The UCaRI process involves first generating a bilayer film
of a randomly packed nanoparticle layer atop a polymer layer, such
that the volume of the polymer is less than the void volume in the
nanoparticle packing. Subsequently, the bilayer film is annealed above
the glass transition temperature of the polymer to induce polymer
infiltration into the voids of the nanoparticle packing. Using in situ spectroscopic ellipsometry and molecular dynamics
simulations, we observe that the polymer transport occurs in two stages:
capillarity-induced infiltration, followed by gradual spreading, likely via surface diffusion. By varying the annealing time, UCaRI
enables the generation of graded or uniform nanoporous PINFs. We also
show that these nanoporous PINFs have tunable optical and mechanical
properties, which can be tailored simply by changing the nanoparticle
to polymer layer thickness ratio in the initial bilayer. The UCaRI
approach is versatile and widely applicable to various polymers, which
allows generation of nanoporous PINFs for multiple applications.