Preparation and electromagnetic wave absorption of compressible graphene aerogels

Pingan Lu, Chenbo Liao, Dongjiu Zhang, Dongqing Liu, Mohamed M. Ibrahim, Haifeng Cheng, Mohammed A. Amin, Taishan Cao, Yingjun Deng, Wei Xie, Zeinhom M. El-Bahy, Zhanhu Guo

Research output: Contribution to journalArticlepeer-review

2 Citations (Scopus)

Abstract

In this study, a developed easy-operation method was adopted to generate ultralight and compressible graphene aerogels by using graphene oxide and ammonia. By changing the process parameters, such as reduction temperature, reducing agent content and ammonia concentration, the variation laws of the density and pore size of aerogels were obtained, which aided in realizing the controllable preparation of aerogel structures. The prepared graphene aerogel has good compressive performance, and its density can reach 5.26 mg/cm 3. Although it was repeatedly compressed 200 times under a load that was 4000 times as large as its own weight, it maintained its structural integrity and mechanical properties. An ideal model of three-dimensional graphene aerogel was constructed, and the electromagnetic wave absorption performance was simulated using the Computer Simulation Technology (CST) Microwave Studio software. The results showed that when the thickness, pore size and height of the sheet were 1.4, 5 and 14 mm, respectively, an optimal electromagnetic wave absorption effect of −31.08 dB could be obtained. Furthermore, the effects of thickness, pore size and height of the sheet on the electromagnetic wave absorption performance are revealed, which provide a reference for the structural design of aerogels with both compressibility and electromagnetic wave absorption performance.

Original languageEnglish
Pages (from-to)88-103
Number of pages16
JournalEmerging Materials Research
Volume13
Issue number2
Early online date4 Mar 2024
DOIs
Publication statusPublished - 1 Jun 2024

Keywords

  • composites
  • compressibility
  • electromagnetic wave absorption performance
  • functional nanomaterials
  • graphene aerogel
  • porous

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