Acoustic-pressure-assisted engineering of aluminium foams

TL;DR

This paper introduces an acoustic-pressure-assisted method to precisely control bubble size in aluminium foams, supported by theoretical modeling and experimental validation, with implications for thermoelectric applications.

Contribution

It provides a detailed theoretical and experimental framework for tuning bubble size in aluminium foams using acoustic pressure, advancing materials engineering techniques.

Findings

The method accurately predicts bubble size modulation in aluminium melts.

Foaming alters electrical and thermal properties, enhancing thermoelectric performance.

The foam exhibits increased thermoelectric figure of merit compared to bulk materials.

Abstract

Foaming metals modulates their physical properties, enabling attractive applications where lightweight, low thermal conductivity or acoustic isolation are desirable. Adjusting the size of the bubbles in the foams is particularly relevant for targeted applications. Here we provide a method with a detailed theoretical understanding how to tune the size of the bubbles in aluminium melts in-situ via acoustic pressure. Our description is in full agreement with the high-rate three-dimensional X-Ray radioscopy of the bubble formation. We complement our study with the intriguing results on the effect of foaming on electrical resistivity, Seebeck coefficient and thermal conductivity from cryogenic to room temperature. Compared to bulk materials the investigated foam shows an enhancement in the thermoelectric figure of merit. These results herald promising application of foaming in thermoelectrics materials and devices for thermal energy conversion.