Crystallization molecular composition effects

Volume additivity methods generally do not take into account crystal packing efficiency or molecular conformation effects and thus will afford identical calculated densities for positional and conformational isomers and for compounds that possess different multiples of the same functional group composition. As an example, a volume additivity calculation predicts that l,3,5-trinitro-l,3,5-triazacyclohex-ane (RDX), l,3,5,7-tetranitro-l,3,-5,7-tetraazacyclooctane (a-HMX), and /3-HMX all will possess the same crystal density, 1.783 g/cm [32]. In fact, the experimentally observed densities of these three compounds differ markedly (i.e., 1.806 [33], 1.839 [34], and 1.902 [35], respectively). 

The racemate of the monomer was found to be iso-stractural with its enan-tiomorph, as it crystallizes in the same space group as a sohd solution, where the sec-butyl groups of opposite handedness are disordered. However, an accurate determination of the phase diagram between S(+)l and R(—)1, under equilibrium conditions, revealed the presence of an immiscibiUty gap in the range 60 40 to 40 60 [49]. Therefore, the crystallization of a large batch of racemic 1 under thermodynamically controlled conditions was associated with the precipitation of equal amounts of crystals of either handedness, with a constant internal composition, as defined by the boundaries of the eutectic. The presence of an immiscibihty gap imphes two different effects on the one hand it interferes with the requirements of an absolute asymmetric synthesis from racemic 1, while on the other hand it provides a most efficient way in which to amplify chirahty via the crystalhzation of nonracemic mixtures of compositions, which are outside the boundaries of the eutectic. Enantiopure oHgomers could be generated from mixtures of molecular composition R S of 60 40 [50]. 

Quite early solution blend work by Takayanagi et al. [83] of rigid aromatic polyamides (poly(p-phenylene terephthalate)) (PPTA) and flexible aliphatic polyamides, nylon 66 and nylon 6 (the latter will be discussed here) has been instrumental in developing the concept of molecular composites and although this lies more in the realm of lyotropic blends, it is often cited in the literature with regard to the effect of the PLC on the crystallization of other components in blends. PPTA has the structure... 

The development of composite micro/mesoporous materials opens new perspectives for the improvement of zeolytic catalysts. These materials combine the advantages of both zeolites and mesoporous molecular sieves, in particular, strong acidity, high thermal and hydrothermal stability and improved diffusivity of bulky molecules due to reduction of the intracrystalline diffusion path length, resulting from creation of secondary mesoporous structure. It can be expected that the creation of secondary mesoporous structure in zeolitic crystals, on the one hand, will result in the improvement of the effectiveness factor in hydroisomerization process and, on the other hand, will lead to the decrease of the residence time of products and minimization of secondary reactions, such as cracking. This will result in an increase of both the conversion and the selectivity to isomerization products. 

Heat-up rate effects have been investigated with respect to microwave synthesis of AlPO phases, however there are few publications concerning the heat-up effects in conventional heating [58]. There has also been at least one study of pH and H2O level on aluminophosphate crystallization [59]. A recent paper attempts to study the unique crystallization process of several aluminophosphate molecular sieve compositions [60]. 

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