Superior noise control using graphene

Superior noise control using graphene
Credit: University of Adelaide

Noise is a dangerous worldwide environmental pollutant: at normal levels found in cities it can induce annoyance, stress and fluctuations in sleep patterns which in turn increase the risk of type-2 diabetes, arterial hypertension, myocardial infarction, and stroke.

A new high-tech low-cost soundproofing foam invented at the University of Adelaide could help keep our cities quiet.

Currently, porous or fibrous materials are used for absorption. Many of these are ineffective or limited by delicacy, excessive weight and thickness, poor moisture insulation, or high temperature instability.

Julker Nine and colleagues at the University of Adelaide saw a way to build a better sound-absorbing material using graphene, a material made of sheets of carbon a thick.

By engineering the internal structure of conventional acoustic absorptive foam using interconnected graphene sheets, the team managed to enhance noise absorption as well as mechanical robustness, moisture insulation and fire retarding qualities.

This new graphene-enhanced foam absorbs about 60 per cent more noise at frequencies between 128 Hz and 4000 Hz compared to commercially available melamine .

The new material is inexpensive to fabricate, scalable and can be adapted for extensive applications in residential structure, aviation and the automobile industry.


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Citation: Superior noise control using graphene (2019, February 13) retrieved 24 June 2019 from https://phys.org/news/2019-02-superior-noise-graphene.html
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