Enhancing the acoustic-to-electrical conversion efficiency of nanofibrous membrane-based triboelectric nanogenerators by nanocomposite composition

Acoustic energy is difficult to capture and utilise in general. The current work proposes a novel nanofibrous membrane-based (NFM) triboelectric nanogenerator (TENG) that can harvest acoustic energy from the environment. The device is ultra-thin, lightweight, and compact. The electrospun NFM used in the TENG contains three nanocomponents: polyacrylonitrile (PAN), polyvinylidene fluoride (PVDF), and multi-walled carbon nanotubes (MWCNTs). The optimal concentration ratio of the three nanocomponents has been identified for the first time, resulting in higher electric output than a single-component NFM TENG. For an incident sound pressure level of 116 dB at 200Hz, the optimised NFM TENG can output a maximum open-circuit voltage of over 120V and a short-circuit current of 30μA, corresponding to a maximum areal power density of 2.25W/m2. The specific power reached 259μW/g. The ability to power digital devices is illustrated by lighting up 62 light-emitting diodes in series and powering other devices. The findings may inspire the design of acoustic NFM TENGs comprising multiple nanocomponents, and show that the NFM TENG can promote the utilisation of acoustic energy for many applications, such as microelectronic devices and the Internet of Things. [Display omitted] •Develop ultra-thin, lightweight, and compact NFM TENG for sound waves.•Improve acoustic-to-electrical conversion efficiency by NFM combinations.•Identify optimal concentration ratio of nanocomponents for the first time.•Higher areal power density of 2.25W/m2 than single-layer PVDF TENGs.•Introduce specific power as a factor of energy harvesting performance.