Your search keyword '"ELECTRIC properties of silver nanoparticles"' showing total 2 results

1. Improved Thermoelectric Performance of Silver Nanoparticles-Dispersed Bi2Te3 Composites Deriving from Hierarchical Two-Phased Heterostructure.

Author

Zhang, Qihao, Ai, Xin, Wang, Lianjun, Chang, Yanxia, Luo, Wei, Jiang, Wan, and Chen, Lidong

Subjects

*ELECTRIC properties of silver nanoparticles, *THERMOELECTRIC materials, *BISMUTH telluride, *PHONON scattering, *HETEROJUNCTIONS

Abstract

A practical and feasible bottom-up chemistry approach is demonstrated to dramatically enhance thermoelectric properties of the Bi2Te3 matrix by means of exotically introducing silver nanoparticles (AgNPs) for constructing thermoelectric composites with the hierarchical two-phased heterostructure. By regulating the content of AgNPs and fine-tuning the architecture of nanostructured thermoelectric materials, more heat-carrying phonons covering the broad phonon mean free path distribution range can be scattered. The results show that the uniformly dispersed AgNPs not only effectively suppress the growth of Bi2Te3 grains, but also introduce nanoscale precipitates and form new interfaces with the Bi2Te3 matrix, resulting in a hierarchical two-phased heterostructure, which causes intense scattering of phonons with multiscale mean free paths, and therefore significantly reduce the lattice thermal conductivity. Meanwhile, the improved power factor is maintained due to low-energy electron filtering and excellent electrical transport property of Ag itself. Consequently, the maximum ZT is amazingly found to be enhanced by 304% arising from the hierarchical heterostructure when the AgNPs content reaches 2.0 vol%. This study offers an easily scalable and low-cost route to construct a wide range of multiscale hierarchically heterostructured bulk composites with significant enhancement of thermoelectric performance. [ABSTRACT FROM AUTHOR]

Published

2015

2. Highly Robust Indium-Free Transparent Conductive Electrodes Based on Composites of Silver Nanowires and Conductive Metal Oxides.

Author

Zilberberg, Kirill, Gasse, Felix, Pagui, Richie, Polywka, Andreas, Behrendt, Andreas, Trost, Sara, Heiderhoff, Ralf, Görrn, Patrick, and Riedl, Thomas

Subjects

*ROBUST optimization, *COMPOSITE materials, *METALLIC oxides, *ATOMIC layer deposition, *ELECTRIC properties of silver nanoparticles, *SOLAR cell efficiency

Abstract

A hybrid approach for the realization of In-free transparent conductive layers based on a composite of a mesh of silver nanowires (NWs) and a conductive metal-oxide is demonstrated. As metal-oxide room-temperature-processed sol-gel SnO x or Al:ZnO prepared by low-temperature (100 °C) atomic layer deposition is used, respectively. In this concept, the metal-oxide is intended to fuse the wires together and also to 'glue' them to the substrate. As a result, a low sheet resistance down to 5.2 Ω sq-1 is achieved with a concomitant average transmission of 87%. The adhesion of the NWs to the substrate is significantly improved and the resulting composites withstand adhesion tests without loss in conductivity. Owing to the low processing temperatures, this concept allows highly robust, highly conductive, and transparent coatings even on top of temperature sensitive objects, for example, polymer foils, organic devices. These Indium- and PEDOT:PSS-free hybrid layers are successfully implemented as transparent top-electrodes in efficient all-solution-processed semitransparent organic solar cells. It is obvious that this approach is not limited to organic solar cells but will generally be applicable in devices which require transparent electrodes. [ABSTRACT FROM AUTHOR]

Published

2014