Palladium chemistry polymers

The synthesis of polymers with pendant arylamines has also been accomphshed using palladium chemistry. For example, reaction of poly(4-bromostyrene) with a diarylamine containing a pendant azobenzene occurred to give the modified polymer in good yield. 

Palladium chemistry with alkene, alkyne, and enyl ligands has deep implications for palladium-catalyzed organic syntheses and in polymer chemistry. The importance of these catalytic reactions is enormous, and new developments... 

The commercial process for the production of vinyl acetate monomer (VAM) has evolved over the years. In the 1930s, Wacker developed a process based upon the gas-phase conversion of acetylene and acetic acid over a zinc acetate carbon-supported catalyst. This chemistry and process eventually gave way in the late 1960s to a more economically favorable gas-phase conversion of ethylene and acetic acid over a palladium-based silica-supported catalyst. Today, most of the world s vinyl acetate is derived from the ethylene-based process. The end uses of vinyl acetate are diverse and range from die protective laminate film used in automotive safety glass to polymer-based paints and adhesives. 

Y. Li, G. Vamvounis, J. Yu, and S. Holdcroft, A novel and versatile methodology for functionalization of conjugated polymers. Transformation of poly(3-bromo-4-hexylthiophene) via palladium-catalyzed coupling chemistry, Macromolecules, 34 3130-3132, 2001. 

Cross-conjugated trienes have attracted interest in polymer chemistry and theoretical chemistry as well as in synthetic chemistry.11 Although a palladium complex catalyzed 1,2-propadiene dimerization in the presence of water or an amine produced hydroxylated or aminated 2,3-dimethyl-2,3-butadiene,12 the method was not applied to the synthesis of cross-conjugated trienes. Another interesting feature... 

In this chapter we will discuss some aspects of the carbonylation catalysis with the use of palladium catalysts. We will focus on the formation of polyketones consisting of alternating molecules of alkenes and carbon monoxide on the one hand, and esters that may form under the same conditions with the use of similar catalysts from alkenes, CO, and alcohols, on the other hand. As the potential production of polyketone and methyl propanoate obtained from ethene/CO have received a lot of industrial attention we will concentrate on these two products (for a recent monograph on this chemistry see reference [1]). The elementary reactions involved are the same formation of an initiating species, insertion reactions of CO and ethene, and a termination reaction. Multiple alternating (1 1) insertions will lead to polymers or oligomers whereas a stoichiometry of 1 1 1 for CO, ethene, and alcohol leads to an ester. 

The most common oxidation state of palladium is H-2 which corresponds toa electronic configuration. Compounds have square planar geometry. Other important oxidation states and electronic configurations include 0 ( °), which can have coordination numbers ranging from two to four and is important in catalytic chemistry, and +4 (eft), which is octahedral and much more strongly oxidizing than platinum (IV). The chemistry of palladium is similar to that of platinum, but palladium is between 103 to 5 x 10s more labile (192). A primary industrial application is palladium-catalyzed oxidation of ethylene (see Olefin polymers) to acetaldehyde (qv). Palladium-catalyzed carbon—carbon bond formation is an important organic reaction. 

Lightowler, S. and Hird, M. (2004) Palladium-catalyzed cross-coupling reactions in the synthesis of novel aromatic polymers. Chemistry of Materials ... 

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