Nanoparticles chemistry

Frigoli M, Ouadahi K, Larpent C (2009) A cascade FRET-mediated ratiometric sensor for Cu2+ ions based on dual fluorescent ligand-coated polymer nanoparticles. Chemistry 15 8319-30... 

Yang, D.Q., B. Hennequin, and E. Sacher, XPS Demonstration ofn-n interaction between benzyl mercaptan and multiwalled carbon nanotubes and their use in the adhesion ofPt nanoparticles. Chemistry of Materials, 2006.18(21) p. 5033-5038. 

Adschiri T. Supercritical hydrothermal synthesis of organic-inorganic hybrid nanoparticles. Chemistry Letters. 2007 36 1188-1193. 

Fig. 20. In vitro cumulative release of radiolabeled fibroblast growth factor (bFGF) in PBS at 22 °C and 37 °C. Nanoparticle chemistry was same as in Fig. 3, except 0.00215 % bFGF was added in place of CC. The amount of bFGF captured (EE) was 7 %. This number also includes losses in the labeling process, as well. Concentration of nanoparticles was approximately 2.5 mg per batch (volume 0.5 mL)...

Nenoff, T. M., Jacobs, B. W., Robinson, D. B. et al. 2011. Synthesis and low temperature in situ sintering of uranium oxide nanoparticles. Chemistry of Materials 23 5185-5190. 

The versatile chemical, photochemical and photophysical behaviour of metal complexes arising from the diverse range of electronic states accessed through several types of perturbation has stimulated increasing interest in metal-centred systems over the last decades. More recently, additional impetus has been created within the broad area of materials, especially in the context of nanoparticle chemistry and physics. The manifold of states of various orbital types that are accessible in mono- and multi-nuclear metal complexes remains key to the continuing interest in their investigation. This includes both fundamental and applied research topics, the latter directed towards the development of novel devices, in particular those driven by optical, thermal or other means. 

Jana, N. R., GeaihearfL., et al. Evidence for Seed-Mediated Nucleation in the Chemical Reduction of Gold Salts to Gold Nanoparticles. Chemistry of materials, 3(7), 2313-2322 (2001). 

R.W.J. Scott, H. Ye, R.R. Hemiquez, R.M. Crooks, Synthesis, Characterization, and Stability of Dendrimer-Encapsulated Palladium Nanoparticles, Chemistry of Materials 15, 3873, 2003. 

It is worthwhile mentioning a new direction in physicochemistry of nanoparticles chemistry of gigantic clusters. A number of synthesis methods for com-pormds with metal-metal links whose nuclearity reaches several hundreds have been elaborated lately. It was noted earlier that severe conditions of synthesis (i.e., the large specific area Sjp of nanoparticles, which is also characterized by small-size morphological elements) can induce variations in the nanoparticles physicochemical properties and even the violation of the expected atomic structure. Extremely high (or low) temperatures and velocities of the processes and various outer effects (e.g., fast condensation or quenching) assist in formation of nonequilibrium, so-called frozen states in growing y-nuclei particles. 

In conclusion, all the examples discussed in this section require more attentiOTi with respect to architectural control when aiming at high (amplified) performance. At the same time, the nanoparticle chemistry used in most of these cases is quite simple, basically due to the physical nature of the processes responsible for amplification and a great variety of conventional chromophore systems can be employed in these MEF-based applications. 

Dhas, N. A. Raj, C. P. Gedanken, A. (1998). Synthesis, Characterization, and Properties of Metallic Copper Nanoparticles, Chemistry of Materials, V0I.IO, p>p.l446-1452, ISSN 0897-4756... 

Li, Y.Q., Fu, S.Y., Yang, Y, and MaL YW. (2008) Facile synthesis of highly transparent polymer nanocomposites by introduction of core-shell stmctured nanoparticles. Chemistry of Materials, 20, 2637-2643. 

Chang, J.S., Kong, Z.L., Hwang, D.F. and Chang, K.L.B. (2006) Chitosan-catalyzed aggregation during the biomimetic synthesis of silica nanoparticles. Chemistry of Materials, 18, 702-7. 

Guldevall, K., Pazik, R., K pinski, L Kvashnina, K.O., Butorin, S Brismar, H., Onfelt, B Osterlund, L., Seisenbaeva, GA., and Kessler, V.G. (2012) Visualization of custom-tailored iron oxide nanoparticles chemistry, uptake, and toxicity. Nanoscale, 4, 7383-7393. 

Perelshtein, 1., et al., A One-Step Process for the Antimicrobial Finishing of Textiles with Crystalline TiO Nanoparticles. Chemistry— A European Journal, 2012,18(15), 4575 582. 

Yang, J.G., Zhou, Y.-L, Okamoto, T., Bessho, T., Satake, S., Ichino, R. and Okido, M. (2005) Preparation of oleic acid-capped copper nanoparticles. Chemistry Letters, 35,1190-1. 

Synthesis, characterization, and properties of metaDic copper nanoparticles. Chemistry of Materials, 10, 1446 52. 

Rucareanu, S., Gandubert, V.J. and Lennox, R.B. (2006) 4-(N,N-Dimethylamino)pyridine-protected Au nanoparticles versatile precursors for water- and organic-soluble gold nanoparticles. Chemistry of Materials, 18, 4674-80. 

Jana, N.R., Gearheart, L. and Murphy, C.J. (2001) Evidence for seed-mediated nucleation in the chemical reduction of gold salts to gold nanoparticles. Chemistry of Materials, 13, 2313-22. 

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