We present a facile and effective route to fabricate monolithic nanoporous silver (NPS) ribbons through chemical dealloying of melt-spun Al-Ag alloys comprising R-Al(Ag) and Ag 2 Al under free corrosion conditions. The microstructure of the NPS ribbons was characterized using X-ray diffraction (XRD), scanning electron microscopy (SEM), transmission electron microscopy (TEM), and energy dispersive X-ray analysis (EDX). The experimental results show that alloy composition and dealloying solution have a significant influence on the dealloying process and the formation of NPS. The Al-Ag alloys with 15-40 atom % Ag can be fully dealloyed in the 5 wt % HCl solution, but a minor amount of undealloyed Ag 2 Al can be detected in the as-dealloyed ribbons from the Al-45 and 50 Ag alloys. The existence of R-Al(Ag) can supply penetration paths for the solution and promote the dealloying of Ag 2 Al in the two-phase Al-Ag alloys. Moreover, the synergetic dealloying of R-Al(Ag) and Ag 2 Al in the two-phase Al-Ag alloys and fast surface diffusion of Ag result in the formation of NPS with a homogeneous porous structure. The Al-Ag alloys with 15-50 atom % Ag cannot be fully dealloyed in the 20 wt % NaOH solution, leading to the formation of NPS/Ag 2 Al composites. In addition, the Al-60 Ag alloy containing a single Ag 2 Al phase does not react with the 5 wt % HCl or 20 wt % NaOH solution even at high temperatures (90 ( 5°C).
IntroductionNanoporous materials have attracted great interest for their wide applications in catalysis, 1-3 gas sensors, 4-6 heat exchangers, 7 supercapacitors, 8 and so on, because of their novel physical, chemical, and mechanical properties associated with their high surface-to-volume ratio and low densities.Nanoporous metal materials can be prepared by metal organic deposition and liquid crystal template technique, 9,10 but they are generally technically difficult and time-consuming to be implemented. Recently, chemical and electrochemical dealloying is usually used to fabricate nanoporous metals by selective dissolution of less noble elements from an alloy because of its high productivity and controllability. Taking the dealloying of a binary A x B 1-x alloy (here, A is a less noble element, and B is a more noble element) in the electrolyte as an example, A will be dissolved from the alloy while B remains. Following the dissolution process of A, the residual B will gradually agglomerate and form a nanoporous structure throughout the dimensions of the sample.Although different alloy systems such as Ni-Al, 11 Cu-Au, 12 Pt-Cu, 13 and Pt-Si 14 have been used to study the dealloying process and the formation of nanoporous metals, most attention has been paid to the prototypical Ag-Au system. [15][16][17][18] In contrast, little information is available on the synthesis of monolithic nanoporous silver (NPS) through dealloying. To date, the research on the preparation of NPS has merely focused on the electrochemical alloying/dealloying process. Jia et al. 19 and Yeh et al. 20 independently succeeded in the fabric...
