Influence of self-assembly conditions on film formation, optical and electrical properties of gold Nanoparticle network film

被引：0

作者：

机构：

[1] Institute of Technology and Science, University of Tokushima, Minami-josanjima, Tokushima

[2] Graduate School of Advanced Technology and Science, University of Tokushima, Minami-josanjima, Tokushima

来源：

Yonekura, Daisuke | 1600年 / Society of Materials Science Japan卷 / 63期

关键词：

Gold nanoparticle; Localized surface plasmon resonance; Optical property; Resistivity; Self-assembly;

D O I：

10.2472/jsms.63.763

中图分类号：

学科分类号：

摘要：

Gold nanoparticles were grown under various sodium citrate concentration and self-assembled gold nanoparticle films were formed on a glass substrate under various conditions to examine the effect of sodium citrate concentration on the particle size of gold nanoparticles and the effect of processing time and processing temperature on the optical properties and electrical resistivity of the self-assembled gold nanoparticle film. As a result, it was found that the ratio of tetrachloroauric (III) acid to sodium citrate is preferably 1:3 was appropriate to obtain fine gold nanoparticles. The self-assembled gold nanoparticle films showed a network structure formed by nano-wires for all assembled conditions. However the thickness or the assembled state of the gold nano-wires was sensitive to the processing temperature whereas the processing time hardly affected the properties of the nano-wires. In particular, higher processing temperature led to a break in the nano-wires and then the optical properties and electrical resistivity was degraded. © 2014 The Society of Materials Science, Japan.

引用

页码：763 / 769

页数：6

共 14 条

[1]

Catchpole K.R., Poleman A., Design principles for particle plasmon enhanced solar cells, Applied Physics Letters, 93, 19, pp. 1911131-1911133, (2008)

[2]

Beck F.J., Polman A., Catchpole K.R., Tunable light trapping for solar cells using localized surface plasmons, Journal of Applied Physics, 105, 11, pp. 1143101-1143107, (2009)

[3]

Pors A., Uskov A.V., Willatzen M., Protsenko I.E., Control of the input efficiency of photons into solar cells with plasmonic nanoparticles, Optics Communications, 284, 8, pp. 2226-2229, (2011)

[4]

Pedrueza E., Valdes J.L., Chirvony V., Abargues R., Hernandez-Saz J., Herrera M., Molina S.I., Martinez-Pastor J.P., Novel method of preparation of gold-nanoparticle-doped TiO2 and SiO2 plasmonic thin films: Optical characterization and comparison with maxwell-garnett modeling, Advanced Functional Materials, 21, 18, pp. 3502-3507, (2011)

[5]

Bastide S., Nychyporuk T., Zhou Z., Fave A., Lemiti M., Facile metallization of dielectric coatings for plasmonic solar cells, Solar Energy Materials &Solar Cells, 102, pp. 26-30, (2012)

[6]

Schaadt D.M., Feng B., Yu E.T., Enhanced semiconductor optical absorption via surface plasmon excitation in metal nanoparticles, Applied Physics Letters, 86, 6, pp. 0631061-0631063, (2005)

[7]

Derkacs D., Lim S.H., Matheu P., Mar W., Yu E.T., Improved performance of amorphous silicon solar cells via scattering from surface plasmon polaritons in nearby metallic nanoparticles, Applied Physics Letters, 89, 9, pp. 0931031-0931033, (2006)

[8]

Pillai S., Catchpole K.R., Trupke T., Green M.A., Surface plasmon enhanced silicon solar cells, Journal of Applied Physics, 101, 9, pp. 0931051-0931058, (2007)

[9]

Spinelli P., Ferry V.E., Groep J., Lare M., Verschuuren M.A., Schropp R.E.I., Atwater H.A., Polman A., Plasmonic light trapping in thin-film Si solar cells, Journal of Optics, 14, 2, pp. 0240021-02400211, (2012)

[10]

Suzuki M., Niidome Y., Kuwahara Y., Terasaki N., Inoue K., Yamada S., Surface-enhanced nonresonance raman scattering from size-and morphology-controlled gold nanoparticle films, The Journal of Physical Chemistry B, 108, 31, pp. 11660-11665, (2004)

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