Reference literature crystallizers

As on previous occasions, the reader is reminded that no very extensive coverage of the literature is possible in a textbook such as this one and that the emphasis is primarily on principles and their illustration. Several monographs are available for more detailed information (see General References). Useful reviews are on future directions and anunonia synthesis [2], surface analysis [3], surface mechanisms [4], dynamics of surface reactions [5], single-crystal versus actual catalysts [6], oscillatory kinetics [7], fractals [8], surface electrochemistry [9], particle size effects [10], and supported metals [11, 12]. 

The variety of molecules used to prepare LB films is enonnous. and only a small selection of examples can be presented here. Liquid crystals and biomolecules such as phospholipids, for example, can also be used to prepare LB films. The reader is referred to tire literature for infonnation about individual species. 

The few references in the literature indicated that glycerol had only been obtained in the crystalline state by chance. Inquiry among places storing large quantities of glycerol finally revealed some crystals at the plant of the Giant Powder Company at Manoose Bay, BC. 

The morphology of polymer crystals has been studied extensively by many experimentalists, and an enormous variety and richness has been unveiled (see e.g. Ref. [5]). It is beyond the scope of this review to lay out the evidence in detail. We can only concentrate on some selected points and refer the interested reader to the literature, in particular the review articles by Keller [6], Bassett [7], Dosiere [8] and most recently Phillips [9],... 

There is a very rich literature and a comprehensive book6 on the role of promoters in heterogeneous catalysis. The vast majority of studies refers to the adsorption of promoters and to the effect of promoters on the chemisorptive state of coadsorbed species on well characterized single crystal surfaces. A... 

A number of systems which in polymer literature are normally referred to as mesophases are obtained under kinetic control. Examples are the smectic phase of isotactic polypropylene [18,19], mesomorphic syndiotac-tic polypropylene [20-22], mesomorphic PET [23,24], and other instances where intermediate degrees of order result after quenching polymers from the melt to temperatures often close to Tg. In these cases disorder is plausibly more static than in bundles close to T0 and these phases usually crystallize upon heating to an appropriate temperature in the stable crystal phases. 

Most of the force fields described in the literature and of interest for us involve potential constants derived more or less by trial-and-error techniques. Starting values for the constants were taken from various sources vibrational spectra, structural data of strain-free compounds (for reference parameters), microwave spectra (32) (rotational barriers), thermodynamic measurements (rotational barriers (33), nonbonded interactions (1)). As a consequence of the incomplete adjustment of force field parameters by trial-and-error methods, a multitude of force fields has emerged whose virtues and shortcomings are difficult to assess, and which depend on the demands of the various authors. In view of this, we shall not discuss numerical values of potential constants derived by trial-and-error methods but rather describe in some detail a least-squares procedure for the systematic optimisation of potential constants which has been developed by Lifson and Warshel some time ago (7 7). Other authors (34, 35) have used least-squares techniques for the optimisation of the parameters of nonbonded interactions from crystal data. Overend and Scherer had previously applied procedures of this kind for determining optimal force constants from vibrational spectroscopic data (36). 

It is clear that kinetic effects must be utilized in the design of a process to make the commercially available Form A, because it is never the most thermodynamically stable form. Information from the literature and patents in reference [14] indicates that Form A can be successfully isolated from Acetonitrile, Acetone, Methyl isobutyl ketone, Toluene, the C2 to C4 alkenols, Ethanol, Methanol and Propan-2-ol. In these solvents it is likely that solvation is favourable to the nucleation rate of Form A or detrimental to crystal growth of the other forms, or both. For a new development compound there should be similar solvent interaction data available from polymorph screening experiments. 

---