石墨烯气凝胶用于超宽带热声学

F. De Nicola, S. Sarti, Bing Lu, L. Qu, Zhipan Zhang, A. Marcelli, S. Lupi
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引用次数: 1

摘要

声音通常是由机电振动结构在介质中产生的。结构的几何尺寸和惯性决定了声转导机制中的频率截止,通常需要不同的振动结构来覆盖从次声到超声的整个范围。另一种没有发射体物理运动的机制是热声效应,其中声音是通过导电材料中的焦耳加热产生的。在这里,我们展示了基于石墨烯气凝胶的单个热声换能器可以发射从次声(1hz)到超声波(20mhz)的超宽带声音,并且没有谐波失真。由于传统的声学换能器由于其转导机制而受到频带限制,超宽带石墨烯气凝胶可能为传统的高保真扬声器、次声和超声换能器提供有效的替代方案。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Graphene Aerogels for Ultrabroadband Thermoacoustics
Sound is usually generated in a medium by an electromechanical vibrating structure. The geometrical size and inertia of the structure set the frequency cutoff in the sound-transduction mechanism and, often, different vibrating structures are necessary to cover the whole range from infrasound to ultrasound. An alternative mechanism without any physical movement of the emitter is the thermoacoustic effect, where sound is produced by Joule heating in a conductive material. Here we show that a single thermoacoustic transducer based on a graphene aerogel can emit ultrabroadband sound from infrasound (1 Hz) to ultrasound (20 MHz), with no harmonic distortion. Since conventional acoustic transducers are frequency band limited due to their transduction mechanism, ultrabroadband graphene aerogels may offer a valid alternative to conventional hi-fi loudspeakers, and infrasound and ultrasound transducers.
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