4.6 Article

A resilient and lightweight bacterial cellulose-derived C/rGO aerogel-based electromagnetic wave absorber integrated with multiple functions

Journal

JOURNAL OF MATERIALS CHEMISTRY A
Volume 9, Issue 9, Pages 5566-5577

Publisher

ROYAL SOC CHEMISTRY
DOI: 10.1039/d0ta11122h

Keywords

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Funding

  1. National Natural Science Foundation of China [51803191]
  2. National Key R&D Program of China [2019YFA0706802]
  3. China Postdoctoral Science Foundation [2018M642782]
  4. Postdoctoral Research Grant in Henan Province [001801007]
  5. 111 project [D18023]
  6. Key Scientific and Technological Project of Henan Province [202102210038]
  7. Major projects of Ningbo

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This study developed an aerogel-based electromagnetic wave (EMW) absorber with multiple functions, including piezoresistive sensing, infrared stealth, thermal insulation, and Joule heating. The aerogel demonstrated excellent EMW absorption performance, stable piezoresistive sensing, effective thermal infrared stealth, thermal insulating properties, and adjustable Joule heating performance, paving the way for high-performance EMW absorption materials with multiple functions.
Considering the complex actual environments and fields, the effective integration of multiple functions into one material is greatly and urgently required but still faces enormous challenges. Herein, an aerogel-based electromagnetic wave (EMW) absorber with the functions of piezoresistive sensing, infrared stealth, thermal insulation, and Joule heating was developed. Biomass bacterial cellulose (BC) and GO work as the carbon resource and reinforcing filler, respectively, obtaining a resilient (80% compression strain) and lightweight (7.81 mg cm(-3)) BC-derived C/thermal reduced GO (rGO) aerogel with the unidirectional cellular structure via the unidirectional freeze-drying and pyrolysis techniques. Remarkably, the prepared aerogel displayed the typical rGO loading and compression strain-dependent EMW absorption performance, and a significant improvement in the EMW absorption capacity with a minimum reflection loss (RLmin) of -46.11 dB and maximum effective absorption bandwidth (EAB(max)) of 9.12 GHz at the thickness of 2.70 mm was achieved for C/rGO-10 (10 wt% rGO loading) when a 70% compression strain was applied compared to that in the natural state. Moreover, the aerogel also presented other attractive features, including stable, durable, and fast responsive piezoresistive sensing performances, effective thermal infrared stealth, and thermal insulating properties, and exceptional adjustable Joule heating performance. This study paves the way for developing high-performance EMW absorption materials with multiple functions to meet various applications.

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