Abstract
In the packaging industry, the barrier property of packaging materials is of paramount importance. The enhancement of barrier properties of materials can be achieved by adding impermeable nanoparticles into thin polymeric films, known as mixed-matrix membranes (MMMs). Three-dimensional numerical simulations were performed to study the barrier property of these MMMs and to estimate the effective membrane gas permeability. Results show that horizontally-aligned thin cuboid nanoparticles offer far superior barrier properties than spherical nanoparticles for an identical solid volume fraction. Maxwell’s model predicts very well the relative permeability of spherical and cubic nanoparticles over a wide range of the solid volume fraction. However, Maxwell’s model shows an increasingly poor prediction of the relative permeability of MMM as the aspect ratio of cuboid nanoparticles tends to zero or infinity. An artificial neural network (ANN) model was developed successfully to predict the relative permeability of MMMs as a function of the relative thickness and the relative projected area of the embedded nanoparticles. However, since an ANN model does not provide an explicit form of the relation of the relative permeability with the physical characteristics of the MMM, a new model based on multivariable regression analysis is introduced to represent the relative permeability in a MMM with impermeable cuboid nanoparticles. The new model possesses a simple explicit form and can predict, very well, the relative permeability over an extensive range of the solid volume fraction and aspect ratio, compared with many existing models.
Highlights
The diameter was varied whereas, for a cuboid nanoparticle, the relative thickness, yp /Ly, and the aspect ratio q were varied in order to assess the effect of the size and the shape of nanoparticles on the relative permeability (Pr ) of Matrix Membranes (MMMs)
MMMs with cuboid nanoparticles with an aspect ratio larger than unity was lower than the relative permeability of membranes with spherical nanoparticles
The Maxwell’s and similar models predict the relative permeability of MMMs with spherical nanoparticles very well, within a wide particle size range
Summary
Barrier thin films are widely used in food and beverage packaging, coating, drug release, fuel cells, and batteries [1,2,3]. Many of these films are made of polymer materials, of which the barrier properties are constrained due to the limitation in their thicknesses. By adding impermeable inorganic fillers into the polymeric matrix of the thin films, the permeation of water and gas molecules in barrier materials is further prevented or delayed. The embedding of a homogenously-dispersed inorganic filler into the continuous phase of a polymeric matrix is typically referred to as a mixed-matrix membrane (MMM). Wolf et al [3]
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