Scope for Future Work

Despite these differences, the similarities predominate and virtually all the features noted for spin crossover in iron(II) are also found for iron(III). Because of the great emphasis on the cooperative aspects of the spin crossover phenomenon, iron(II) systems have tended to dominate more recent research. However, there are very striking examples among the iron(III) systems which are of strong relevance to these aspects and there is certainly scope for future work in this area. This is evident in much of the very recent work where it can be seen that specific strategies to increase the cooperativity have been successful and have led, for example, to solid iron(III) systems which display the LIESST effect [137, 138]. The generation of polymeric species as a means of increasing cooperativity, an approach which has been widely adopted for iron(II), has received relatively little attention for iro-n(III) and this is an area which can be expected to be exploited further. 

Examples where this "globalization" of phase space structures in the reaction region has been carried out can be found in Refs. [24-26, 46]. However, there is tremendous scope for future work in this direction, both from the point of view of mathematical and computational techniques and applications to chemical dynamics. 

Adding to this, there may be alternative polymer combinations - the matrix does not have to be PLLA. In fact, there may even be biodegradable polymer combinations for MFC in which, for example, PLLA is the reinforcing component surrounded by a ductile matrix. Furthermore, additional drawing steps could be added to maximize the orientation of the reinforcing polymer as well as decrease fibril diameters. A very interesting overlap of MFCs and particulate composites provides even more potential for Improvement and scope for future work because, as mentioned before, nanoparticles could be used to modify the reinforcing polymer s thermal properties to enhance creep resistance. 

The rest of the chapter is organized as follows Section 2 describes the problem the proposed AGO is explained and illustrated in section 3 Section 4 presents a numerical illustration for the proposed AGO Section 5 presents the performance study of the proposed AGO for various benchmark instances and Section 6 concludes with scope for future work... 

There is much scope for future work on molecules containing lower elements of Groups V and VI. 

Srlvastava, 1978 Scott, 1978 Thomson, 1979 Malik, 1981 Parmar et al., 1981). There Is lot of scope for future work which might enable the seeds of doubtful quality to perform better besides Improving the performance of good quality seeds. 

Finally, a potential application of molecular metal clusters which is virtually unexplored is the intentional generation of colloidal metal particles and the production of slurry phase catalysts (Table I). This may offer scope for future work. 

All of the methods are hmited to s-ds-enones (chalcones generally seem to work best) and much work remains to be done to expand the range of alkenes to include s-trans-enones, unsaturated esters, and imsaturated nitriles. There is, therefore, considerable scope for future research in this area. 

It is beyond the scope of this review to be exhaustive in the field of supercooled liquids that has drawn intense research activities over several decades. Reviews that are exclusive for this field and deal with specific topics in considerable detail are recommended for supplemental reading [9-11]. In view of the scope this chapter, the next section provides the readers with a brief introduction to the systems of interest and associated nomenclature. Section III sets up the background by reviewing experimental results on the dynamics of thermotropic liquid crystals across the I-N transition, then introducing the central issues in the dynamics of supercooled liquids, and finally comparing the dynamics of the two systems in the light of recent experiments. Section IV presents a summary of some of the well-known theoretical approaches to liquid crystals. Section V provides a detailed account of computational efforts. Finally, we conclude in Section VI with a list of problems for future work. 

Unquestionably the best way to achieve that end would have been to rewrite the book, to expand its size and its scope, along some lines which are still unconventional but hold out promise for future interest. The prospect of undertaking this frightened us. Also, we acknowledge that there already exists a monumental treatise of this elaborate sort, dedicated to the standard parts of the newer mathematics, in the work of Morse and Feshbach, whose excellence would be hard to approach. We, therefore, decided upon the less ambitious course of editing a work which offers what we regard as the most important components of today s useful mathematics in separate chapters written chiefly by experts. 

The presented approach for future inventory planning can be only a first proposal in the specific scope of this work with significant potential for further research. 

Any assumptions made in preparing the cost estimate should be clearly stated as they form a basis for future negotiations with the client if the field conditions warrant a variance from the proposed scope of work. 

Clearly, despite a tremendous body of available literature, the essential details of the mechanism of oxygen reduction on carbon surfaces remain obscure and, unfortunately, even more experimental work will be needed to elucidate it. However, a judicious and yet unexplored guide for future studies is readily available, based on the principle of microscopic reversibility the reaction of carbon surfaces with hydrogen peroxide (in the absence of an electric field). Even a cursory analysis of this arguably fruitful topic is beyond the scope of the present review, however. Suffice it to say that the pH dependence of ORR is of interest. It was studied, for example, by Yang and McCreery [246],... 

As seen from this review, CO2 diemistry is likely to have its second rebirth when it is extended to systems with transition metal participation. Even the first results disclose numerous possibilities for using CO2 in different chemical processes in the future. The industrial chemist is especially interested in producing usable compounds which are formed from the cheap chemical CO2. Further research should be done on the hydrocarboxylatton reactions of alkenes whereby saturated or unsalurated carboxylic acids are obtained. Aromatics or alkanes with activated hydrogen should also be possible reaction partners of carb(Hi dioxide. Future work will extend our knowledge of the scope of transition metal-C02 chemistry and of the potential uiUity of carbon dioxide as a feedstock for the production of organic chemicals. 

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