Синтез и химическое модифицирование поверхности анизотропных наночастиц серебра (1105736), страница 22
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4252-4258.50.Kazeminezhad I., Barnes A.C., Holbrey J.D., Seddon K.R., Schwarzacher W. Templatedelectrodeposition of silver nanowires in a nanoporous polycarbonate membrane from anonaqueous ionic liquid electrolyte // AP. l. Phys. A. 2007. V. 86. № 3. P. 373-375.51.Riveros G., Green S., Cortes A., Gomez H., Marotti R. E., Dalchiele E.
A. Silvernanowire arrays electrochemically grown into nanoporous anodic alumina templates //Nanotechnology 2006. V. 17. P. 561–570.52.Sun B., Jiang X., Dai S., Du Z. Single-crystal silver nanowires: Preparation and Surface-enhanced Raman Scattering (SERS) property // Mater. Lett. 2009. V. 63. P. 2570–2573.53.Zhang S.-H., Xie Z.-X., Jiang Z.-Y., Xu X., Xiang J., Huang R.-B., Zheng L.-S.Synthesis of silver nanotubes by electroless deposition in porous anodic aluminium oxidetemplates // Chem. Commun., 2004. P. 1106 – 1107.54.Wei G., Zhou H., Liu Z., Song Y., Wang L., Sun L., Li Z.
One-SteP. Synthesis of SilverNanoparticles. Nanorods. and Nanowires on the Surface of DNA Network // J. Phys. Chem. B2005. V. 109. P. 8738-8743.55.Wiley B., Sun Y., Xia Y. Synthesis of Silver Nanostructures with Controlled Shapes andProperties // Acc. Chem.
Res. 2007. V. 40. P. 1067–1076.14256.Sun. Y.; Xia. Y. Shape-Controlled Synthesis of Gold and Silver Nanoparticles // Science.2002. V. 298 № 5601 P. 2176-2179.57.Skrabalak, S. E.; Wiley, B. J.; Kim, M.; Formo, E.; Xia, Y. On the polyol synthesis ofsilver nanostructures: glycolaldehyde as a reducing agent. // Nano Lett. 2008. V. 8. P. 20772081.58.Xia Y., Xiong Y., Lim B., Skrabalak S.E.
Shape-controlled synthesis of metalnanocrystals: simple chemistry meets complex physics // Angew. Chem. Int. Ed. 2009. V. 48. P.60-103.59.Zhang Q., Li W., Moran C., Zeng J., Chen J., Wen L.P. , Xia Y. Seed-mediated synthesisof Ag nanocubes with controllable edge lengths in the range of 30-200 nm and comparison oftheir optical properties // J. Am. Chem. Soc. 2010. V.
132. P. 11372-11378.60.Jana. N. R.; Gearheart. L.; Murphy. C. Seed-Mediated Growth AP. roach for Shape-Controlled Synthesis of Spheroidal and Rod-like Gold Nanoparticles Using a SurfactantTemplate // 2001. V. 13. № 18. P. 1389–1393.61.Pietrobon B., McEachran M., Kitaev V. Synthesis of Size-Controlled Faceted PentagonalSilver Nanorods with Tunable Plasmonic Properties and Self-Assembly of These Nanorods //ACS Nano.
2009. V. 3. P. 21–26.62.Sun Y., Yin Y., Mayers B. T., Herricks T., Xia Y., Uniform silver nanowire synthesis byreducing AgNO3 with ethylene glycol in the presence of seeds and poly(vinyl pyrrolidone) //Chemistry of Materials. 2002. V. 14. 4736-4745.63.Edited by Masuda Y. Nanocrystal // InTech. 2011. P. 88.64.Söderlund J., Kiss L.B., Niklasson G.A., Granqvist C.G. Lognormal size distributions inparticle growth processes without coagulation // Phys. Rev. Lett.
1998. V. 80. №. 11. P. 23862388.65.Granqvist C. G., Buhrman R. A. Ultrafine metal particles // Journal of AP. l. Phys. 1976.V. 47. №. 5. P. 2200-2219.66.Maillard M., Giorgio S., Pileni M.-P. Tuning the size of silver nanodisks with similaraspect ratios: synthesis and optical properties. // J. Phys. Chem. B. 2003. V. 107. P.
2466–247067.Kind Ch., Popescu R., Muller E., Gerthsenb D., Feldmann C. Microemulsion-basedsynthesis of nanoscaled silver hollow spheres and direct comparison with massive particles ofsimilar size. // Nanoscale. 2010. V. 2. P. 2223–2229.68.Ni C. Y., Hassan P. A., Kaler E.
W. Structural Characteristics and Growth of PentagonalSilver Nanorods Prepared by a Surfactant Method // Langmuir. 2005. V. 21. P. 3334–3337.14369.Chang M.-H., Cho H.-A., Kim Y.-S., Lee E.-J., Kim J.-Y. Thin and long silver nanowiresself-assembled in ionic liquids as a soft template: electrical and optical properties // NanoscaleResearch Letters. 2014.
V. 9. P. 330.70.Liu R., Li S., Yu X., Zhang G., Ma Y, Yao J., Keita B., Nadjo L. Polyoxometalate-Assisted Galvanic Replacement Synthesis of Silver Hierarchical Dendritic Structures // Cryst.Growth Des., 2011. V. 11. № 8. P. 3424–3431.71. Dalchiele E.A., Marotti R.E., Cortes A., Riveros G., Gomez H., Martınez L., Romero R.,Leinen D., Martind F., Ramos-Barrado J.R. Silver nanowires electrodeposited into nanoporoustemplates: Study of the influence of sizes on crystallinity and structural properties // Physica E.2007. V. 3 184–188.72.Sun X.-Y., Xu F.-Q., Li Z.-M., Zhang W.-H. Cyclic voltammetry for the fabrication ofhigh dense silver nanowire arrays with the assistance of AAO template // Mater.
Chem. Phys..2005. V. 90. P. 69–72.73.Sauer G., Brehm G., Schneider S., Nielsch K., Wehrspohn R. B. Highly orderedmonocrystalline silver nanowire arrays // J. AP. l. Phys., 2002. V. 91. № 5. P. 3243-3247.74.Xu X. J., Fei G. T., Wang X. W., Jin Z., Yu W. H., Zhang L. D. Synthetic control oflarge-area. ordered silver nanowires with different diameters // Mater. Lett.
2007. V. 61. P. 19–22.75.Ланин С. Н., Пичугина Д. А., Шестаков А. Ф., Смирнов В. В., Николаев С. А.,Ланина К. С., Васильков А. Ю., Зунг Ф. Т., Белецкая А. В. Адсорбция углеводородов накластерахзолота–экспериментиквантово-химическоемоделирование//Ж.физич.химии. 2010.
т. 84. № 12. с. 1–11.76.Murphy C. J., Sau T. K., Gole A. M., Orendorff C. J., Gao J., Gou L., Hunyadi S E., Li T.Anisotropic Metal Nanoparticles: Synthesis. Assembly. and Optical AP. lications // J. Phys.Chem. B. 2005. Vol. 109. 13857-1387077.Bai J., Qin Y., Jiang C., Qi L. Polymer-controlled synthesis of silver nanobelts andhierarchical nanocolumns // Chemistry of Materials 2002. V. 14. № 11.
P. 4736-4745.78.Jana N. R., Gearheart L., Murphy C. J. Wet chemical synthesis of silver nanorods andnanowires of controllable aspect ratio // Chemical Communications 2001. № 6. P. 617-618.79.Sun Y., Yin Y., Mayers B. T., Herricks T., Xia Y. Uniform silver nanowires synthesis byreducing agno3 with ethylene glycol in the presence of seeds and poly(vinyl pyrrolidone) //Chem. Mat. 2002. V.
14. № 11. P. 4736-4745.80.Sun Y., Xia Y. Large-Scale Synthesis of Uniform silver nanowires through a soft. self-seeding. polyol process // Adv. Mater. 2002. V. 14. № 11. P. 833-837.14481.Marks L. D. Experimental studies of small particle structures // Reports on Progress inPhysics 1994. V. 57. № 6. P. 603-649.82.Murphy C. J., Gole A. M., Hunyadi S. E., Orendorff C. J. One-dimensional colloidal goldand silver nanostructures // Inorg. Chem. 2002.
V. 298. № 12. P. 2176-2179.83.Anacker. E. W., Micelle formation of cationic surfactants in aqueous media. in CationicSurfactants. Jungermann. E. Edited by Marcel Dekker. New York. 1970. P. 217.84.Zou X., Ying E., Chen H., Dong S. An aP. roach for synthesizing nanometer- tomicrometer-sized silver nanoplates // Coll. Surf. A. 2007. V.
303. № 3. P. 226-234.85.Ledwith D. M., Whelan A. M., Kelly J. M. A rapid. straight-forward method forcontrolling the morphology of stable silver nanoparticles // J. Mat. Chem. 2007. V. 17. № 23. P.2459-2464.86.Chen S., Fan Z., Carroll D. L. Silver nanodisks: synthesis. characterization. and self-assembly // J.
Phys. Chem. B 2002. V. 106. № 42. P. 10777-10781.87.Xiong Y., Washio I., Chen J., Cai H., Li Z-Y., Xia Y. Poly(vinyl pyrrolidone): a dualfunctional reductant and stabilizer for the facile synthesis of noble metal nanoplates in aqueoussolutions // Langmuir 2002. V. 106.
№ 42. P. 10777-10781.88.Sun Y., Mayers B., Xia Y. Transformation of silver nanospheres into nanobelts andtriangular nanoplates through a thermal process // Nano Letters 2003. V. 3. № 5. P. 675-679.89.Jin R., Cao Y. W., Mirkin C. A., Kelly K. L., Schatz G.
C., Zheng J. G. Photoinducedconversion of silver nanospheres to nanoprisms // Science. 2001. V. 294. P. 1901-1903.90.Wang L.Y., Xu L.M., Zhuang W.C., Chai Y.C., Yang C.J. CaP. ing effect of CTAB onpositively charged Ag nanoparticles. // Physica E 2006. V. 33. P. 308-31491.Thomas K.
G., Zajicek J., Kamat P.V. Surface Binding Properties ofTetraoctylammonium Bromide-CaP. ed Gold Nanoparticles.// Langmuir 2002. V. 18. P. 3722372792.Son S. U., Jang Y., Yoon K. Y., Kang E., Hyeon T. Facile synthesis of variousphosphine-stabilized monodisperse palladium nanoparticles through the understanding ofcoordination chemistry of the nanoparticles// Nano Letters. 2004.
V. 4. № 6. P. 1147-1151.93.Mishra T., Sahu R.K.,LimS.-H., Salamanca-RibaL.G.,Bhattacharjee S.Hexadecylamine caP. ed silver and gold nanoparticles: Comparative study on formation andself-organization // Mater. Chem. Phys. 2010. V. 123. P. 540–545.94.Strong. L., Whitesides G.M. The Structures of Self-Assembled Monolayer Films ofOrganosulfur Compounds Adsorbed on Gold Single Crystals: Electron Diffraction Studies//.Langmuir. 1988. V. 4. P. 546-558.14595.Love J.C., Estroff L.A., Kriebel J.K., Nuzzo R.G., Whitesides G.M.
Self-AssembledMonolayers of Thiolates on Metals as a Form of Nanotechnology // Chem. Rev. 2005. V. 105.P. 1103-116996.Nuzzo R. G., Allara D. L. Adsorption of bifunctional organic disulfides on gold surfaces//J.Am. Chem. Soc. 1983. V. 105. P. 4481–4483.97.Poirier G. E. and Pylant E. D. The self-assembly mechanism of alkanethiols on Au(111)//Science. 1996. V. 272. P. 1145-1148.98.Kumar A., Biebuyck H. A., and Whitesides G. M. Patterning Self-AssembledMonolayers: AP. lications in Materials Science // Langmuir 1994. V.10.
P. 1498-151199.Laibinis, P. E., Whitesides G. M., Allara D.L.,Tao Y.T., Parikh A.N., Nuzzo R.G.Comparison of the structures and wetting properties of self-assembled monolayers of nalkanethiols on the coinage metal surfaces. coP. er. silver. and gold.// J.Am. Chem. Soc. 1991.V.113. №19. P. 7152-7167.100.Fenter P. , Eisenberger P.
, Li J., Camillone III N., Bernasek S., Scoles G.,Ramanarayanan T. A., Liang K. S. The Structure of CH3(CH2)17SH Self-Assembled on theAg(111) Surface: An Incommensurate Monolayer. // Langmuir. 1991. V. 7. P. 2013.101.Love J. C., Wolfe D.B. Chabinyc M. L., Paul K. E., Whitesides G. M. Formation andstructure of self-assembled monolayers of alkanethiolates on palladium // J.Am. Chem. Soc.2003. V. 125. №9.P.
2597-2609.102.Ulman A., Formation and Structure of Self-Assembled Monolayers // Chem. Rev. 1996.V. 96. P. 1533−1554.103.Johnson S. R., Evans S. D., Brydson R. Influence of a terminal functionality on thephysical properties of surfactant-stabilized gold nanoparticles // Langmuir 1998. V.
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