Size dependent microstructure for Ag–Ni nanoparticles

Srivastava, C. ; Chithra, S. ; Malviya, K.D. ; Sinha, S.K. ; Chattopadhyay, K. (2011) Size dependent microstructure for Ag–Ni nanoparticles Acta Materialia, 59 (16). pp. 6501-6509. ISSN 1359-6454

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Official URL: http://doi.org/10.1016/j.actamat.2011.07.022

Related URL: http://dx.doi.org/10.1016/j.actamat.2011.07.022

Abstract

The Ag–Ni system is characterized by large differences in atomic sizes (14%) and a positive heat of mixing (+23 kJ mol−1). The binary equilibrium diagram for this system therefore exhibits a large miscibility gap in both solid and liquid state. This paper explores the size-dependent changes in microstructure and the suppression of the miscibility gap which occurs when free alloy particles of nanometer size are synthesized by co-reduction of Ag and Ni metal precursors. The paper reports that complete mixing between Ag and Ni atoms could be achieved for smaller nanoparticles (LT7 nm). These particles exhibit a single-phase solid solution with face-centered cubic (fcc) structure. With increase in size, the nanoparticles revealed two distinct regions. One of the regions is composed of pure Ag. This region partially surrounds a region of fcc solid solution at an early stage of decomposition. Experimental observations were compared with the results obtained from the thermodynamic calculations, which compared the free energies corresponding to a physical mixture of pure Ag and Ni phases and a fcc Ag–Ni solid solution for different particle sizes. Results from the theoretical calculations revealed that, for the Ag–Ni system, solid solution was energetically preferred over the physical mixture configuration for particle sizes of 7 nm and below. The experimentally observed two-phase microstructure for larger particles was thus primarily due to the growth of Ag-rich regions epitaxially on initially formed small fcc Ag–Ni nanoparticles.

Item Type:Article
Source:Copyright of this article belongs to Elsevier Science
Keywords:Miscibility gap;Nanoparticles;Electron microscopy;Composition;Gibbs free energy
ID Code:135374
Deposited On:23 Jan 2023 04:56
Last Modified:24 Jan 2023 03:38

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