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Electricity future development

Abstract In this paper the synthesis, properties and applications of poly(organophos-phazenes) have been highlighted. Five different classes of macromolecules have been described, i.e. phosphazene fluoroelastomers, aryloxy-substituted polymeric flame-retardants, alkoxy-substituted phosphazene electric conductors, biomaterials and photo-inert and/or photo-active phosphazene derivatives. Perspectives of future developments in this field are briefly discussed. [Pg.166]

Although the field of nonlinear optics has traditionally been the stronghold of the physics and electrical engineering disciplines, if many of the potential applications are to be realized materials science and chemistry must play a role in its future development. A parallel can be drawn between the multidisciplinary effort that has been responsible for the tremendous progress in integrated electronic circuitry in recent years, and the need to combine the development of nonlinear media with sophisticated physical characterization and exploration of new nonlinear phenomena, in order for progress to be sustained. [Pg.258]

The success of polymer semiconductors in the marketplace, however, depends critically on the ability of these materials to sustain their electrical performance under operation - unstable devices are of little practical use. In this chapter we will describe known issues in the stability of polymer TFTs and point out some of the challenges that must be addressed in the future development of these materials. [Pg.108]

We shall conclude this chapter with a few speculative remarks on possible future developments of nonlinear IR spectroscopy on peptides and proteins. Up to now, we have demonstrated a detailed relationship between the known structure of a few model peptides and the excitonic system of coupled amide I vibrations and have proven the correctness of the excitonic coupling model (at least in principle). We have demonstrated two realizations of 2D-IR spectroscopy a frequency domain (incoherent) technique (Section IV.C) and a form of semi-impulsive method (Section IV.E), which from the experimental viewpoint is extremely simple. Other 2D methods, proposed recently by Mukamel and coworkers (47), would not pose any additional experimental difficulty. In the case of NMR, time domain Fourier transform (FT) methods have proven to be more sensitive by far as a result of the multiplex advantage, which compensates for the small population differences of spin transitions at room temperature. It was recently demonstrated that FT methods are just as advantageous in the infrared regime, although one has to measure electric fields rather than intensities, which cannot be done directly by an electric field detector but requires heterodyned echoes or spectral interferometry (146). Future work will have to explore which experimental technique is most powerful and reliable. [Pg.348]

All these bioelectrocatalytic functions of redox proteins are based on the control and enhancement of the electrical communication between the redox sites of the proteins and the electrode support. This is accomplished by the nano-engineering of the surfaces with covalently anchored proteins, the structural aligmnent of the proteins on the electrodes and the chemical modification of the proteins with redox-active units. Preliminary results suggest that two approaches will play important roles in the future development of bioelectronic systems (i) protein mutagenesis with specific functional amino acid residues that can align the protein on the electrode surface and control the electrical contact with the electrode (ii) the synthesis of de novo proteins with tailored bioelectronic and electrobiocatalytic functions. [Pg.2567]

In this chapter we have mentioned only a few of the more important future developments which can be foreseen in colloid science. Many of these will depend on the availability of modern instrumentation and of powerful computer facilities. In addition to the techniques dealt with in this chapter, mention should also be made of the contributions from greatly improved electron microscopic techniques, ultracentrifuges, and X-ray equipment. Other techniques that will become of increasing significance include dielectric measurements, electrical birefringence, and time-resolved fluorescence. [Pg.209]


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See also in sourсe #XX -- [ Pg.38 ]




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