Sentence examples for behavior of these blends from inspiring English sources
The effects of ABS type and blend composition on the morphological, rheological and mechanical behavior of these blends were explored at a fixed (5 wt.%) compatibilizer content.
In order to understand the unexpected decrease in ductility, the crystallization behavior of these blends was characterized by transmission electron microscopy and in-situ Raman spectroscopy.
On the basis of phase separation temperatures (Ts) for poly methyl methacrylate)/poly styrene-co-acrylonitrile) blends of different compositions, measured by small angle laser light scattering, we have studied dynamic rheological behavior of these blends at different temperatures below, near and above Ts.
These experiments reemphasize both the importance of the softening/melting regime to the development of morphology in low-viscosity-ratio, miscible blends, and the dynamic similarity between the behavior of these miscible blends and their immiscible counterparts at short mixing times.
Our results show that the interfacial behavior of these elastomeric blends is a direct function of the BIMS chemical composition.
Crystallization behavior of these polyester blends played an important role in determination of the surface physicochemical properties including surface free energy, chemical states and polarity, and could subsequently govern the cellular responses.
The miscibility and thermal behavior of these PBZ/PCL blends were investigated by differential scanning calorimetry (DSC), dynamic mechanical analysis (DMA), Fourier transform infrared spectroscopy (FTIR), and solid state 13C nuclear magnetic resonance (NMR) spectroscopy.
DSC analysis and spectral-birefringence technique were used to understand the thermal and stress-induced crystallization behavior of the blends.
The morphology and dynamic mechanical behavior of the blends were studied using scanning electron microscopy (SEM) and dynamic mechanic thermal analysis (DMTA).
The curing behavior of the blends of imide monomer and APCB was investigated by FT-IR and DSC.
The thermal and dynamic viscoelastic behavior of the blends have been examined and compared to the unmodified epoxy matrix.
