Electroless Deposition and Ignition Properties of Si/Fe(2)O(3) Core/Shell Nanothermites

[Image: see text] Thermite, a composite of metal and metal oxide, finds wide applications in power and thermal generation systems that require high-energy density. Most of the researches on thermites have focused on using aluminum (Al) particles as the fuel. However, Al particles are sensitive to electrostatic discharge, friction, and mechanical impact, imposing a challenge for the safe handling and storage of Al-based thermites. Silicon (Si) is another attractive fuel for thermites because of its high-energy content, thin native oxide layer, and facile surface functionality. Several studies showed that the combustion properties of Si-based thermites are comparable to those of Al-based thermites. However, little is known about the ignition properties of Si-based thermites. In this work, we determined the reaction onset temperatures of mechanically mixed (MM) Si/Fe(2)O(3) nanothermites and Si/Fe(2)O(3) core/shell (CS) nanothermites using differential scanning calorimetry. The Si/Fe(2)O(3) CS nanothermites were prepared by an electroless deposition method. We found that the Si/Fe(2)O(3) CS nanoparticles (NPs) had a lower reaction onset temperature (∼550 °C) than the MM Si/Fe(2)O(3) nanothermites (>650 °C). The onset temperature of the Si/Fe(2)O(3) CS nanothermites is also insensitive to the size of the Si core NP. These results indicate that the interfacial contact quality between Si and Fe(2)O(3) is the dominant factor for determining the ignition properties of thermites. Finally, the reaction onset temperature of the Si/Fe(2)O(3) CS NPs is comparable to that of the commonly used Al-based nanothermites, suggesting that Si is an attractive fuel for thermites.