LAUSR

Abstract This paper reviews current knowledge about the rheology and applications of highly concentrated molten polymers, focusing on hard particles with sizes ranging from several 100 s nm to a few microns. Understanding the rheological properties should assist the formulation and processing of such polymeric materials. The main factors affecting the rheological behavior of these composites are discussed, such as size distribution, nature and shape of the particles, interactions, maximum packing fraction and matrix viscosity. The matrix viscosity is a key parameter that has to be optimized to be low enough to enable the material processing and high enough to improve the dispersion. The size polydispersity of the fillers facilitates higher filling levels and decreases the melt mixture viscosity for a given filler content. The different types of interactions (viz. particle-particle, particle-matrix) are described to interpret the phenomena arising during processing better. On the other hand, mixing is of particular importance to reach high-quality dispersion and distribution of the particles in the matrix in order to obtain a homogenous mixture and desirable properties. The mixing methods and tools to characterize the degree of mixing are reviewed. The use of organic dispersants is generally necessary to improve and control the dispersion degree and flow properties. Mathematical models relating the viscosity as a function of the filler content for unimodal and bimodal highly filled suspensions are summarized. Constraints and flow instabilities often lead to non-linear rheological behavior such as wall slip, particle-binder segregation, swelling and surface instabilities phenomena; these are discussed. Finally, the latest applications for highly filled systems (such as solid propellants, flame retardancy, magnetic materials, ceramic materials, batteries, etc.) are presented as a source of inspiration for industrial improvements.