Polymer blends microscopy

Flammiche A, Flourston D J, Pollock FI M, Reading M and Song M 1996 Scanning thermal microscopy sub-surface imaging, thermal mapping of polymer blends, localised calorimetry J. Vac. Sol. Technol. B 14 1486... 

There are tests for physical properties such as deasity and hardness (qv) of plastics. Microscopy (qv) is important ia fracture analysis as well as ia analysis of the morphology of polymer systems for an understanding of polymer blend performance. 

Characterization and control of interfaces in the incompatible polymer blends were reported by Fayt et al. [23]. They used techniques such as electron microscopy, thermal transition analysis, and nonradiative energy transfer (NRET), etc. They have illustrated the exciting potentialities offered by diblock copolymers in high-performance polymer blends. 

Electron microscopy, 16 464, 487-495 history of, 16 487-488 in polymer blend morphology determination, 20 339-340 of PVC particles, 25 658-659 of silica, 22 371-372 in surface and interface imaging, 24 75-80... 

Confocal fluorescence microscopy has been extensively used in cell biology. Single living cells can indeed be studied by this technique visualization of organelles, distribution of electrical potential, pH imaging, Ca2+ imaging, etc. (Lemasters, 1996). Interesting applications in chemistry have also been reported in the fields of colloids, liquid crystals and polymer blends. 

Note For a polymer blend or composite, the morphology describes the structures and shapes observed, often by microscopy or scattering techniques, of the different phase domains present within the mixture. 

Tihe technological properties and the commercial application of several polymer blends have been studied extensively. Investigations of the basic principles, however, relating the phase structure of the blends to the properties of the individual components have not been carried out to an extent justified by the industrial value of these materials. Several methods have been used, the most successful being optical and electron microscopy and dynamic-mechanical measurements. Critical factors and difficulties in the morphological studies of polymer blends have been... 

Changing the milling temperature has a pronounced effect on the mechanical properties (19) and the physical state of the polymer blend (Table I). Figure 6 shows that the permeability and diffusion coefficients decrease considerably on increasing the milling temperature. This decrease can be correlated with the increased amount of very small PVC particles (< 0.2 /on) as observed by electron microscopy. The effect is... 

Several applications of scanning force microscopy (SFM) and related techniques in polymer science have been given in the above sections. The reviewed results were gathered from surfaces of cross-sectioned bulk polymers, polymer-matrix composites, and polymer blends as well as free surfaces of polymer samples such as films, or surfaces prepared by means of replica techniques. The materials contrasts reported on range from several mechanical ones via thermal to electrical ones. 

Raman spectroscopy is sensitive to polymer conformation. For example, a polymer blend of polybutadiene-polystyrene in which polybutadiene is used to increase toughness of the polystyrene can be examined by Raman microscopy to identify its heterogeneity. Polybutadiene has three isomer conformations (cis-1,4, trans-1,4 and syndiotactic-1,2). These three types of isomers can be identified from C=C stretching modes as shown in Figure 9.36. The Raman spectra of the copolymer indicate the difference in amounts of isomer types at the edge and the center of the polybutadiene-polystyrene sample. Relative amounts of these isomer types affect the mechanical properties of the copolymer. 

Applications. Optical microscopy finds several important applications in filled systems, including observation of crystallization and formation of spherulites and phase morphology of polymer blends. " In the first case, important information can be obtained on the effect of filler on matrix crystallization. In polymer blends, fillers may affect phase separation or may be preferentially located in one phase, affecting many physical properties such as conductivity (both thermal and electrical) and mechanical performance. 

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