Abstract
Aluminium alloy foams are created by injecting gas containing different levels of oxygen (from ≪1ppm to 21%) into melts stabilised with SiC or TiB2 particles. Individual liquid aluminium alloy films meant to represent the films in a foam are produced of the same materials. For foams and films, the oxygen concentration of the atmosphere is controlled. Synchrotron X-ray radioscopy on liquid films is applied to track the movements of the particles within and to observe how they flow, pile up and form clusters. Experiments on aluminium foams show that only when the injected gas and the surrounding atmosphere contain oxygen foams can be expanded continuously. In contrast, if foaming is carried out by injecting argon into the melt and the Ar atmosphere is free of oxygen no stable foams can be created, even if the melt contains 20vol.% SiC particles. Both film and foam surfaces are analysed ex-situ by energy-filtered TEM and SEM. It is found that oxide layers form, cover the particles and push them into the metal. A high oxygen content in combination with Mg in the alloy promotes this process. It is concluded that not only particles are required to allow for foaming, but also the formation of an oxide skin is necessary and the combination of both are the basis of film and foam stabilisation.
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