Synthesis of submicron silver powder from scrap low-temperature co-fired ceramic an e-waste: Understanding the leaching kinetics and wet chemistry.
| Autor: | Swain B; Institute for Advanced Engineering (IAE), Advanced Materials & Processing Center, Yongin-Si, 449-863, Republic of Korea. Electronic address: swain@iae.re.kr., Shin D; Institute for Advanced Engineering (IAE), Advanced Materials & Processing Center, Yongin-Si, 449-863, Republic of Korea., Joo SY; Institute for Advanced Engineering (IAE), Advanced Materials & Processing Center, Yongin-Si, 449-863, Republic of Korea., Ahn NK; Institute for Advanced Engineering (IAE), Advanced Materials & Processing Center, Yongin-Si, 449-863, Republic of Korea., Lee CG; Institute for Advanced Engineering (IAE), Advanced Materials & Processing Center, Yongin-Si, 449-863, Republic of Korea., Yoon JH; Institute for Advanced Engineering (IAE), Advanced Materials & Processing Center, Yongin-Si, 449-863, Republic of Korea. Electronic address: yjh6373@iae.re.kr. |
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| Jazyk: | angličtina |
| Zdroj: | Chemosphere [Chemosphere] 2018 Mar; Vol. 194, pp. 793-802. Date of Electronic Publication: 2017 Dec 07. |
| DOI: | 10.1016/j.chemosphere.2017.12.034 |
| Abstrakt: | The current study focuses on the understanding of leaching kinetics of metal in the LTCC in general and silver leaching in particular along with wet chemical reduction involving silver nanoparticle synthesis. Followed by metal leaching, the silver was selectively precipitated using HCl as AgCl. The precipitated AgCl was dissolved in ammonium hydroxide and reduced to pure silver metal nanopowder (NPs) using hydrazine as a reductant. Polyvinylpyrrolidone (PVP) used as a stabilizer and Polyethylene glycol (PEG) used as reducing reagent as well as stabilizing reagent to control size and shape of the Ag NPs. An in-depth investigation indicated a first-order kinetics model fits well with high accuracy among all possible models. Activation energy required for the first order reaction was 21.242 kJ mol -1 for Silver. PVP and PEG 1% each together provide better size control over silver nanoparticle synthesis using 0.4 M hydrazine as reductant, which provides relatively regular morphology in comparison to their individual application. The investigation revealed that the waste LTCC (an industrial e-waste) can be recycled through the reported process even in industrial scale. The novelty of reported recycling process is simplicity, versatile and eco-efficiency through which waste LTCC recycling can address various issues like; (i) industrial waste disposal (ii) synthesis of silver nanoparticles from waste LTCC (iii) circulate metal economy within a closed loop cycle in the industrial economies where resources are scarce, altogether. (Copyright © 2017 Elsevier Ltd. All rights reserved.) |
| Databáze: | MEDLINE |
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