Novel crystalline reduced graphene oxide/adhesive nanocomposites for enhanced electrical, thermal, dielectric properties and electromagnetic energy absorption application

Carbon Research - Tập 1 - Trang 1-13 - 2022
Adil Khan1, Saima Sarfraz2, Ata Ur Rahman3, Sayyar Muhammad4
1Chemistry Division Directorate of Science PINSTECH, Nilore Islamabad, Pakistan
2Central Analytical Facility Division Directorate of System and Services PINSTECH, Nilore Islamabad, Pakistan
3Institute of Chemical Sciences, University of Peshawar, Peshawar, Pakistan
4Department of Chemistry, Islamia College Peshawar, Peshawar, Pakistan

Tóm tắt

At present times electromagnetic (EM) pollution is increasing due to a lot of progress and achievements in the electronics field. There is a dire need to develop materials that have greater EM energy absorption/emission properties. We report here the synthesis of a nanocomposite of carbonaceous material, reduced graphene oxide (rGO) with Chloroprene (CP) grafted polymethyl methacrylate (CP-g-pMMA), i.e. rGO/CP-g-pMMA. FTIR confirms the grafting of Chloroprene rubber and the presence of rGO. XRD shows the crystallinity of rGO alone and in the composites as well. SEM images showed smooth texture for neat polymer while nanocomposite showed a leafy appearance of the reduced graphene oxide (rGO). The viscosity of pure CP was 3740 cps while CP-g-pMMA was 1644 cps. A slight decrease was observed after the addition of rGO. Enhancement in thermal properties from 264 °C to 269 °C showed that the composites were thermally more stable than the virgin CP and CP-g-pMMA. The permittivity and alternating current conductivity were checked by Radio Frequency (RF) impedance and material analyzer in the range of (1–1000 MHz) X-band and (1–3 GHz) S-band. The nanocomposites showed the lowest percolation (0.32 vol. %) yet reported. The nanocomposites showed low real and absolute permittivity. The electrical and permittivity analysis of the rGO/CP-g-pMMA nanocomposites revealed that they can be potential candidates for their applications in electronic devices as an absorber. ➢  The article presents a novel, easy, cost-effective and environmentally friendly synthesis of the nanocomposite, rGO/CP-g-pMMA. ➢  rGO/CP-g-pMMA is thermally more stable than the precursor’s CP and CP-g-pMMA. ➢  Nanocomposites are efficient electromagnetic energy absorption materials. ➢  It has the potential to save electronic circuits from high pulse shock, and reduce electromagnetic pollution and the risk of instrumental damage.

Tài liệu tham khảo

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