Nanoparticle advantages

A second option is to apply the membrane on the particle level (millimeter scale) by coating catalyst particles with a selective layer. As a third option, application at the microlevel (submicrometer scale) is distinguished. This option encompasses, for example, zeolite-coated crystals or active clusters (e.g., metal nanoparticles). Advantages of the latter two ways of application are that there are no sealing issues, it is easy to scale-up, the membrane area is large per unit volume, and, if there is a defect in the membrane, this will have a very limited effect on the overall reactor performance. Because of these advantages, it is believed that using a zeolite... 

Laser ablation of metal targets in liquids provides a rapid and simple method for preparation of stable metal nanoparticles. Advantages of this technique include its versatility with respect to metals or solvents, and the absence of chemical reagents or ions in the final preparation. The developed technique offers a good control over the particles formation process and an effective collection and conservation of fabricated materials. 

The primary goal of the researchers has been to produce Q-dots possessing all of the attributes of the Q-dots prepared using liquid-phase synthetic methods (that is adjustability of the nanocrystal identity and diameter and size monodispersity) and also the technological utility of Q-dots prepared by MBE (specifically, the deposition of nanocrystals with a defined orientation and an electrical output contact). It was shown that the E/C-synthesized 5-CuI and CdS Q-dots were indeed epitaxial with narrow size distribution and strong photoluminescence tunable by the particle size. Qne of the advantages of the E/C method is that it can be made size selective. The key point is that the size as well as the size dispersion of product nanoparticles are directed actually by the corresponding properties of the metal nanoparticles therefore the first deposition step assumes special importance. 

Finally, a second area of research for nanoparticles is their immobihza-tion on various supports. The deposition of well-defined nanoparticles on a support by different methods should advantageously replace traditional heterogeneous catalysts in terms of activity and selectivity. 

Since 1976 until present time Toshima-t5q)e nanocolloids always had a major impact on catalysis and electrocatalysis at nanoparticle surfaces [47,210-213,398-407]. The main advantages of these products lie in the efficient control of the inner structure and morphology especially of bimetallic and even multimetallic catalyst systems. 

In a different way, metallic-core nanoparticles [346-349] (prepared cf. Section 3.10) equipped with biocompatible coats such as L-cysteine or dextrane may be exploited for highly efficient and cell-specific cancer cell targeting, i.e., for improving diagnosis and therapy of human cancer. In a recent proof-of-principle experiment an unexpectedly low toxicity of the L-cysteine-covered cobalt nanoparticles was demonstrated [433] For diagnostic purposes, it is expected to use the advantageous magnetic properties of the metallic-core nanoparticles to obtain a contrast medium for MRI with considerably increased sensitivity, capable to detect micro-metastases in the environment of healthy tissues [434 37]. 

From the viewpoint of size control, bimetallic nanoparticles naturally have a strong tendency to provide monodispersed particles, compared with monometallic nanoparticles [49]. This tendency cannot be completely understood yet, but redox properties between two metals might result in this advantageous properties of bimetallic nanoparticles. 

Advantages of small metal nanoparticles are (i) short range ordering, (ii) enhanced interaction with environments due to the high number of dangling bonds, (iii) great variety of the valence band electron structure, and (iv) self-structuring for optimum performance in chemisorption and catalysis. 

Thermodynamic control (Figure 1, right) is based on adsorption of substances until quasi-equilibrium stage. In this case, the surface ratio of the adsorbed species is defined by the ratio of products of their concentration and binding constant. This deposition is much less influenced by poorly controllable fluctuations of external conditions and provides much better reproducibility. The total coverage can be almost 100%. Because of these reasons, the thermodynamic control is advantageous for preparation of mixed nanostructured monolayers for electrochemical applications including a formation of spreader-bar structures for their application as molecular templates for synthesis of nanoparticles. 

The main advantage of the salt reduction method in the liquid phase is that it is reproducible and allows colloidal nanoparticles with narrow size distribution to be prepared. 

For fundamental studies of nanoparticles in IRAS measurements, a very important issue is how to attach metal nanoparticles onto a conducting substrate without changing their physical and chemical properties. Recently, we have developed a new method for anchoring metallic nanoparticles on reflective substrates of gold and/or glassy carbon, which we have termed a temperature-induced deposition (TID) method [Stamenkovic et al., 2004]. A key advantage of this method is that the catalysts... 

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