Carbon oxygen nitrogen polymers

These Ionic reactions or electron transfer reactions are not what generally occur in the structure of both natural and synthetic polymers. In polymers it is the covalent bond that dominates, and in a covalently bonded structure there is no transfer of electrons from one atom to another. Instead the electrons are shared between the adjacent atoms In the molecule. The commercial polymeric materials that will be covered In this text will generally be based on seven atomic species silicon, hydrogen, chlorine, carbon, oxygen, nitrogen, and sulfur. Figure 2.4 shows these atoms with the number of outer valance electrons. 

Reasonable prediction can be made of the permeabiUties of low molecular weight gases such as oxygen, nitrogen, and carbon dioxide in many polymers. The diffusion coefficients are not compHcated by the shape of the permeant, and the solubiUty coefficients of each of these molecules do not vary much from polymer to polymer. Hence, all that is required is some correlation of the permeant size and the size of holes in the polymer matrix. Reasonable predictions of the permeabiUties of larger molecules such as flavors, aromas, and solvents are not easily made. The diffusion coefficients are complicated by the shape of the permeant, and the solubiUty coefficients for a specific permeant can vary widely from polymer to polymer. 

The permachor method is an empirical method for predicting the permeabiUties of oxygen, nitrogen, and carbon dioxide in polymers (29). In this method a numerical value is assigned to each constituent part of the polymer. An average number is derived for the polymer, and a simple equation converts the value into a permeabiUty. This method has been shown to be related to the cohesive energy density and the free volume of the polymer (2). The model has been modified to liquid permeation with some success. 

Most acrylonitrile-butadiene styrene terpolymer (ABS) is produced as a graft of SAN onto a butadiene polymer backbone. This graft copolymer may be blended with more SAN or acrylonitrile elastomer (NBR) to improve its properties. ABS is more ductile than SAN. The Tt and the heat deflection temperature of ABS vary with the composition, and ABS may have one set of values for the PBD domains and another set for the SAN matrix. The permeabilities of ABS to oxygen, nitrogen, and carbon dioxide are much less than those of hope. 

Permanent Gases. Table 1 lists the permeabilities of oxygen, nitrogen, and carbon dioxide for selected bamer and nonbanier polymers at 20° C and 75% rh. The effect of temperature and humidity are discussed later. For many polymers the permeabilities of nitrogen, oxygen, and carbon dioxide are in the ratio 1 4 14. 

Table 9-2 contains values of P for oxygen, nitrogen, carbon dioxide, and water vapor in some polymers (Brandrup and Immergut, 1989). The values of P cover a range of several orders of magnitude between the highly permeable silicone elastomers and the extremely impermeable EVOH materials. As an example, for 02 at 0 °C P = 3.7E-11 cmV Pa1 in polydimethylsiloxane and P = 7.4E-18 cm2s-1Pa-1 in EVOH at 40 % relative humidity(rh). 

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