Tunable Electromagnetic Interference Shielding Ability in a One-Dimensional Bagasse Fiber/Polyaniline Heterostructure

Zhang, Yang; Yang, Zai; Yu, Ye; Wen, Bianying; Liu, Yiyang; Qiu, Munan

doi:10.1021/acsapm.8b00025

Cited by 71 publications

(41 citation statements)

References 50 publications

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“…Conducting polymer nanocomposites containing carbonaceous nanofillers such as CNTs and graphene have received burgeoning research interests to replace conventional metallic shields due to their high end mechanical and electrical properties (Al-Saleh & Sundararaj, 2009;Chen et al, 2016;Shen, Zhai, & Zheng, 2014;Yan et al, 2015;Yang, Gupta, Dudley, & Lawrence, 2005;Zeng et al, 2016). Moreover, intrinsically conducting polymers such as Polypyrrole (PPy) (Guo et al, 2017;Kaur, Ishpal, & Dhawan, 2012), Polythiophenes (PTs) (Dar et al, 2017;Kulkarni et al, 2019) Poly (3,4-ethylenedioxythiophene) (PEDOT) (Dalal et al, 2019;Luo, Zhang, Mei, Chang, & Yan, 2016) and Polyaniline (PANI) (Joseph, Varghese, & Sebastian, 2015;Zhang et al, 2019) has also been of great interest for EMI shielding applications. Very recently, 2D transition metal carbides and nitrides (MXene) have gathered much attention for developing next generation high performance EMI shielding materials (Cao et al, 2018;Sun et al, 2017;Wang et al, 2019;Weng et al, 2018;Zhao et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Ultra-fast heat dissipating aerogels derived from polyaniline anchored cellulose nanofibers as sustainable microwave absorbers

Pai

Binumol

Gopakumar

et al. 2020

Carbohydrate Polymers

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Electromagnetic (EM) pollution is ubiquitous and has soared to a great extent in the past few decades. The use of plant sourced cellulose nanofibers to fabricate sustainable and high performance electromagnetic shielding materials is foreseen as a green solution by the electronics industry to address this unseen pollutant. In this view, we report a facile and environmentally benign strategy to synthesize ultra-light and highly conductive aerogels derived from cellulose nanofibers (CNF) decorated with polyaniline (PANI) via a simple in-situ polymerization and subsequent freeze drying process devoid of any volatile organic solvents. The obtained conductive aerogels exhibited density as low as 0.01925 g/cc with a maximum EMI shielding value −32 dB in X band region. These porous shields demonstrated strong microwave absorption behavior (95 %) with minimal reflection (5 %) coupled with high specific EMI SE value ∼1667 dB.cm 3 . g −1 which make these aerogels a potential candidate for use in telecommunication, military and defense applications.

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Section: Introductionmentioning

confidence: 99%

Ultra-fast heat dissipating aerogels derived from polyaniline anchored cellulose nanofibers as sustainable microwave absorbers

Pai

Binumol

Gopakumar

et al. 2020

Carbohydrate Polymers

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“…EMI shielding effectiveness (SE) measurements are performed using vector network analyser system (Fig. 3 ) in 1–8 GHz frequency range 20 . Experimentally, EMI SE is measured in decibels (dB) as the logarithmic ratio of incoming power (P I ) to transmitted power (P T ).…”

Section: Resultsmentioning

confidence: 99%

2D nanosheets and composites for EMI shielding analysis

Khan

Aqeel

et al. 2020

Sci Rep

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Liquid exfoliated, 2-dimensional (2D), few layered graphene and molybdenum disulfide nanosheets (GNS and MNS) are size selected for EMI shielding application. Scanning electron microscopy (SEM) has confirmed the lateral dimensions increase (1–2 µm for GNS and MNS) with lowering centrifugation speed (1000 to 500 rpm). The micron size (~ 15 µm) restacked structures of GNS and MNS (L ~ 2 µm) over a nylon membrane have shown ~ 16 dB and ~ 6 dB EMI shielding effectiveness (1–8 GHz frequency), respectively. The enhanced EMI shielding effectiveness for GNS-500 may be credited to its high carrier mobility as well as high aspect ratio of nanosheets. The GNS-500 are further dispersed (0.3 wt.%) in thermoplastic polyurethane for their applicability as flexible EMI shielding material. The dielectric characteristics predicted an enhancement for the attenuation (200 MHz–1 GHz). The experimental results (1–8 GHz) suggested the maximum attenuation ~ 18 dB showing the composite applicability as a broadband EMI shielding material.

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“…A prefabricated conductive skeleton has been proven to outperform a traditional filler-mixed loading − in terms of enlarging conductive loss, particularly in conductive polymer EMI shielding materials. ,,,− Meanwhile, metals, − carbon materials , and intrinsically conductive polymers ,− can be coated on the fiber to also achieve the efficacy of a conductive skeleton. To increase the polarized loss, building heterogeneous interfaces is a novel strategy, and the heterostructure can accumulate sufficient electric charge to weaken the incident electromagnetic waves (EMWs). ,− Typical structures are multilayer materials and core–shell nanostructures. , Moreover, reasonable space structure design of the reflection layer and absorption layer also have great synergistic effects on EMI shielding performance ,,,− in layered materials. In the structure of the “reflection layer (bottom)/absorption layer (top)”, the propagation paths of EMWs will be extended by the high reflection layer at the bottom and the EMWs will be fully consumed by the two layers …”

Section: Introductionmentioning

confidence: 99%

“…15,36−38 Typical structures are multilayer materials 15 and core−shell nanostructures. 36,38 Moreover, reasonable space structure design of the reflection layer and absorption layer also have great synergistic effects on EMI shielding performance 15,17,18,39−43 in layered materials. In the structure of the "reflection layer (bottom)/absorption layer (top)", the propagation paths of EMWs will be extended by the high reflection layer at the bottom and the EMWs will be fully consumed by the two layers.…”

Section: Introductionmentioning

confidence: 99%

Conductive Skeleton–Heterostructure Composites Based on Chrome Shavings for Enhanced Electromagnetic Interference Shielding

Zhang

Yan

Liu

et al. 2020

ACS Appl. Mater. Interfaces

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Renewable bio-based electromagnetic interference (EMI) shielding materials receive increasing attention undoubtedly. However, there is still a challenge to use raw biomass materials to construct a significant structure through an effortless and environmental route for EMI shielding applications. Herein, for the first time, we demonstrated a hybrid composite of multi-walled carbon nanotube/polypyrrole/chrome-tanned collagen fiber (MWCNT/PPy/CF), which utilized waste chrome shavings as a matrix. X-ray photoelectron spectroscopy reveals that the chromium on the CF has a binding effect on the PPy layer, which endows the tight integration between the CF and PPy layer. After the MWCNT network was loaded on the PPy layer, this ternary structure could provide stable conductive paths and a rich number of polarized interfaces. The MWCNT/PPy/CF composite exhibits superior electrical conductivity (354 ± 52 S/m), higher than PPy/CF (222 ± 38 S/m) and MWCNT/CF (104 ± 11 S/m), owing to the synergy of dual conductive structures. Notably, the shielding effectiveness (SE) value of the MWCNT/PPy/CF composite reaches 30 dB in the X band at a thickness of 0.48 mm. The shielding effectiveness of reflection (SER) (9.1 dB) is similar to that of PPy/CF (8.2 dB), while the shielding effectiveness of absorption (SEA) is significantly improved from 15.3 dB (PPy/CF) to 20.4 dB (MWCNT/PPy/CF) due to the additional coverage of the MWCNT network. This indicates the synergy between the MWCNT network and conductive PPy/CF skeleton. This work provided a method to prepare sustainable and low-cost renewable EMI shielding materials using chrome shavings. Meanwhile, this novel structure combining a conductive skeleton and heterostructure can be considered as a potential application in relevant fields.

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Tunable Electromagnetic Interference Shielding Ability in a One-Dimensional Bagasse Fiber/Polyaniline Heterostructure

Cited by 71 publications

References 50 publications

Ultra-fast heat dissipating aerogels derived from polyaniline anchored cellulose nanofibers as sustainable microwave absorbers

Ultra-fast heat dissipating aerogels derived from polyaniline anchored cellulose nanofibers as sustainable microwave absorbers

2D nanosheets and composites for EMI shielding analysis

Conductive Skeleton–Heterostructure Composites Based on Chrome Shavings for Enhanced Electromagnetic Interference Shielding

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