Abstract
The thermal behaviour of Ag2[PtCl4] and Ag2[PtCl6] complex salts in inert and reducing atmospheres has been studied. The thermolysis of compounds in a helium atmosphere is shown to occur in two stages. At the first stage, the complexes decompose in the temperature range of 350–500 °C with the formation of platinum and silver chloride and the release of chlorine gas. At the second stage, silver chloride is sublimated in the temperature range of 700–900 °C, while metallic platinum remains in the solid phase. In contrast to the thermolysis of Ag2[PtCl6], the thermal decomposition of Ag2[PtCl4] at 350 °C is accompanied by significant heat release, which is associated with disproportionation of the initial salt to Ag2[PtCl6], silver chloride, and platinum metal. It is confirmed by DSC measurements, DFT calculations of a suggested reaction, and XRD. The thermolysis of Ag2[PtCl4] and Ag2[PtCl6] compounds is shown to occur in a hydrogen atmosphere in two poorly separable steps. The compounds are decomposed within 170–350 °C, and silver and platinum are reduced to a metallic state, while a metastable single-phase solid solution of Ag0.67Pt0.33 is formed. The catalytic activity of the resulting nanoalloy Ag0.67Pt0.33 is studied in the reaction of CO total (TOX) and preferential (PROX) oxidation. Ag0.67Pt0.33 enhanced Pt nano-powder activity in CO TOX, but was not selective in CO PROX.
Highlights
The search for new efficient energy sources is an important problem nowadays
It is noteworthy that intense heat is released at a temperature of 365 ◦C which could be associated with a phase transition or another process that is not accompanied by a change in mass
Thermolysis of Ag2[PtCl6] and Ag2[PtCl4] compounds in a helium atmosphere occurs in two stages
Summary
The search for new efficient energy sources is an important problem nowadays. One option to solve this problem is to use fuel cells, i.e., devices that convert chemical energy into electrical energy, bypassing the inefficient stage of fuel combustion, which occurs with great losses. Since there is no release of harmful substances into the atmosphere, such elements are eco-friendly, which is very important today due to pressing environmentrelated issues. Fuel cells are promising and have attracted the attention of many researchers [1,2]. Catalysts are important components of fuel cells; they increase the efficiency of the latter. Various catalysts can be used for low-temperature fuel cells, but highly dispersed platinum catalysts on carbon are currently amongst the most popular ones
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