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Nanoengineering

One of the most recent and intrigning developments in the area of colloid science is the surface nanoengineering of colloidal particles in solntion. The self-assembly of macromolec-... [Pg.507]

Caruso, F. (2001) Nanoengineering of partide surfaces. Advanced Materials, 13, 11-22. [Pg.346]

Despite much excitement in the 1990s over the potential for microfluidics and nanoengineering to revolutionize HTS, there have been few commercially viable systems that embody the concept. Most notable is the Caliper capillary electrophoresis... [Pg.66]

Ewels CP, Heggie MI, Briddon PR (2002) Adatoms and nanoengineering of carbon. Chem Phys Lett 351 178... [Pg.267]

Int. Ed., Vol. 43, A.-H. Lu, W. Schmidt, N. Matoussevic, H. Bonnemann, B. Spliethoff, B. Tesche, E. Bill, W. Kiefer, F. Schuth, Nanoengineering of a magnetically separable hydrogenation catalyst, pp. 4303-4306. Copyright 2004. With permission from Wley-VCH.)... [Pg.126]

S.Patachia, M. Rinja. Study of the PVA hydrogel behaviour in boric acid solution. Advances in Micro and Nanoengeneering, Series Micro and Nanoengineering 6, Ed. Academiei Romane, 2004. pp. 140-146. [Pg.178]

The understanding of bio- and chemo-catalytic functionalities, their integration in recognizing materials (doped materials, membranes, tubes, conductive materials, biomarker detection, etc.) and the development of smart composite materials (e.g., bio-polymer-metal) are all necessary elements to reach above objectives. It is thus necessary to create the conditions to realize a cross-fertilization between scientific areas such as catalysis, membrane technology, biotech materials, porous solids, nanocomposites, etc., which so far have had limited interaction. Synergic interactions are the key factor to realizing the advanced nanoengineered devices cited above. [Pg.403]

Cross-fertilization Advanced nanoengineered devices by integration of catalysis, membranes, biotech materials, porous solids, and nanocomposites concepts... [Pg.409]

Ajayan et al., 2003). Both single- and multi-walled carbon nanotubes have become ideal nanoscale-building blocks for nanoengineering. A lot of studies suggest that CNTs have extensive commercial application potential in medical chemistry and biomedical engineering. [Pg.182]

Protein is an excellent natural nanomaterial for molecular machines. Protein-based molecular machines, often driven by an energy source such as ATP, are abundant in biology. Surfactant peptide molecules undergo self-assembly in solution to form a variety of supermolecular structures at the nanoscale such as micelles, vesicles, unilamellar membranes, and tubules (Maslov and Sneppen, 2002). These assemblies can be engineered to perform a broad spectrum of functions, including delivery systems for therapeutics and templates for nanoscale wires in the case of tubules, and to create and manipulate different structures from the same peptide for many different nanomaterials and nanoengineering applications. [Pg.185]

The analysis of single DNA molecules or small self-assemblies is equally important for medical research, e.g., for the understanding of the DNA sequence-dependent and structure-dependent diseases (recently reviewed [48]), as well as for nanoengineering-oriented research, e.g., understanding of the mechanical properties of DNA [49] that are useful for the construction of future nanodevices. In the following section we will refer to the AFM studies concerning DNA molecules and small self-assembhes as single molecule studies . [Pg.126]

Caruso E, Caruso RA, Mohwald H. Nanoengineering of inorganic and hybrid hollow spheres by colloidal templating. Science 1998 282 1111-1114. [Pg.198]

Fig. 3 Concept of nanoengineering of oxide catalytic surface in terms of nanoreactor array, some of the possibilities offered by this concept (in particular in terms of realizing multifunctional catalysts for cascade reactions in nanoconfined liquids) and a SEM image of an array of Xi02 nanotubes produced by anodic oxidation of Ti foils. Source Centi et alN... Fig. 3 Concept of nanoengineering of oxide catalytic surface in terms of nanoreactor array, some of the possibilities offered by this concept (in particular in terms of realizing multifunctional catalysts for cascade reactions in nanoconfined liquids) and a SEM image of an array of Xi02 nanotubes produced by anodic oxidation of Ti foils. Source Centi et alN...
Oldenburg SJ, Averitt RD, Westcott SL, Halas NJ (1998) Nanoengineering of optical resonances. Chem Phys Lett 288 243-247... [Pg.225]

Brown JQ. Modeling, design, and validation of fluorescent spherical enzymatic glucose microsensors using nanoengineered polyelectrolyte coatings. Louisiana Tech University, 2005. [Pg.309]

Chiara Castiglioni Center for NanoEngineered Materials and Surfaces, Politecnico di Milano, Italy... [Pg.626]

J. Fish Bridging the scales in nanoengineering and science. J. Nanopart. Rsrch. 8, 577-594 (2006)... [Pg.125]

Ivanovskaya M., Frolova E., Orlik D. and Gurin V. Proc. of 4th Intern. Conf. on Materials for Microelectronics and Nanoengineering, IOM Communications Ltd., London, UK, 259-262... [Pg.257]

Clearly many aspects of medicinal chemistry, nanoengineering and supramolec-ular chemistry will have to be brought together if functional nanodevices are to be manufactured and used in vivo. The main challenge will be to verify that the devices work as anticipated and, most importantly, cause no harm. [Pg.253]

W. Yantasee, Y. Lin, X. Li, G. E. Fryxell, T. S. Zemanian, and V. V. Viswanathan, Nanoengineered electrochemical sensor based on mesoporous silica thin-film functionalized with thiol-terminated monolayer, Analyst 128, 899-904 (2003). [Pg.334]


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