Abstract
Titania nanotubes (TNTs) impregnated with Pd and Pt nanoparticles are evaluated as heterogeneous catalysts in different conditions in two reactions: catalytic CO oxidation (gas phase, up to 500 °C) and H2O2 direct synthesis (liquid phase, 30 °C). The TNTs are obtained via oxidation of titanium metal and the intermediate layer-type sodium titanate Na2Ti3O7. Thereafter, the titanate layers are exfoliated and show self-rolling to TNTs, which, finally, are impregnated with Pd or Pt nanoparticles at room temperature by using Pd(ac)2 and Pt(ac)2. The resulting crystalline Pd/TNTs and Pt/TNTs are realized with different lengths (long TNTs: 2.0–2.5 µm, short TNTs: 0.23–0.27 µm) and a specific surface area up to 390 m2/g. The deposited Pd and Pt particles are 2–5 nm in diameter. The TNT-derived catalysts show good thermal (up to 500 °C) and chemical stability (in liquid-phase and gas-phase reactions). The catalytic evaluation results in a low CO oxidation light-out temperature of 150 °C for Pt/TNTs (1 wt-%) and promising H2O2 generation with a productivity of 3240 molH2O2 kgPd−1 h−1 (Pd/TNTs, 5 wt-%, 30 °C). Despite their smaller surface area, long TNTs outperform short TNTs with regard to both CO oxidation and H2O2 formation.
Highlights
Specific surface area and pore volume constitute the key parameters of materials used for heterogeneous catalysis [1,2]
We evaluate the catalytic properties of titania nanotubes (TNTs) imIn the following, we evaluate the catalytic properties of titania nanotubes (TNTs) pregnated by Pd or Pt nanoparticles at different conditions, including the catalytic CO
Thesis of the and impregnation the noblethereafter metal thereafter of all, titanium metal metal powder was oxidized in aqueous sodium hydroxide to obtain thethe layer-type titanium powder was oxidized in aqueous sodium hydroxide to obtain layer-type sodium titanate
Summary
Specific surface area and pore volume constitute the key parameters of materials used for heterogeneous catalysis [1,2]. In this regard, several concepts and classes of materials have been discussed and studied. Several concepts and classes of materials have been discussed and studied This includes small-sized nanoparticles and thin films, nanomaterials with special shapes (e.g., tetrapods or spikecubes), particles with inner surfaces and pores (e.g., hollow nanospheres or nanofoams), and high-porosity bulk materials (e.g., metalorganic frameworks (MOFs) or zeolites) [3,4,5,6]. Chemical and thermal stability are naturally highly relevant, since the catalytic reactions require certain activation energy, and elevated temperatures [1,2,3,4,5,6]
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