Construction of CuS Nanoflakes Vertically Aligned on Magnetically Decorated Graphene and Their Enhanced Microwave Absorption Properties

Liu, Panbo; Huang, Ying; Yan, Jing; Yang, Yiwen; Zhao, Yang

doi:10.1021/acsami.5b10511

Cited by 437 publications

(173 citation statements)

References 68 publications

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“…46,47 When it was exposed to air again, the XPS spectra were found to be almost the same as those before exposure to the H 2 S, indicating the transformation from the CuS to CuO.…”

Section: Gas-sensing Mechanismmentioning

confidence: 93%

Room-Temperature High-Performance H₂S Sensor Based on Porous CuO Nanosheets Prepared by Hydrothermal Method

Wang

Lin

et al. 2016

ACS Appl. Mater. Interfaces

227

108

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Porous CuO nanosheets were prepared on alumina tubes using a facile hydrothermal method, and their morphology, microstructure and gas sensing properties were investigated. The monoclinic CuO nanosheets had an average thickness of 62.5 nm and were embedded with numerous holes with diameters ranging 5 nm to 17 nm. The porous CuO nanosheets were used to fabricate gas sensors to detect hydrogen sulfide (H 2 S) operated at room temperature. The sensor showed a good response sensitivity of 1.25 with the respond/recovery time of 234 s and 76 s, respectively, when tested with the H 2 S concentrations as low as 10 ppb. It also showed a remarkably high selectivity to the H 2 S, but only minor responses to other gases such as SO 2 , NO, NO 2 , H 2 , CO and C 2 H 5 OH. The working principle of the porous CuO nanosheets based sensor to detect the H 2 S was identified to be the phase transition from semiconducting CuO to a metallic conducting CuS.

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“…46,47 When it was exposed to air again, the XPS spectra were found to be almost the same as those before exposure to the H 2 S, indicating the transformation from the CuS to CuO.…”

Section: Gas-sensing Mechanismmentioning

confidence: 93%

Room-Temperature High-Performance H₂S Sensor Based on Porous CuO Nanosheets Prepared by Hydrothermal Method

Wang

Lin

et al. 2016

ACS Appl. Mater. Interfaces

227

108

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“…40 Though the EM wave absorption performance of graphene can be dramatically enhanced by adding magnetic materials, the large thickness of the absorbers restricts their further practical applications. [43][44][45] As a classical and important metal oxide, TiO 2 has been widely used in photochemical studies, lithium ion batteries and dielectric materials. 41 It is well known that in addition to impedance matching, the EM wave absorption performance of a material is closely related to the special nanostructures, especially for three-dimensional (3D) nanostructures, and designing and construction of 3D graphene-based composites with extra void space will be interesting for improving EM wave absorption performance due to the complicated geometrical morphologies, multiple reflections and adjustable dielectric and magnetic properties.…”

Section: Introductionmentioning

confidence: 99%

Magnetic graphene@PANI@porous TiO₂ ternary composites for high-performance electromagnetic wave absorption

et al. 2016

Self Cite

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A two-step strategy combining in situ polymerization and a hydrothermal process has been developed for coupling polyaniline (PANI) with porous TiO 2 anchored on magnetic graphene. The microstructure and morphology of magnetic graphene@PANI@porous TiO 2 were characterized by FETEM, FESEM, XRD, XPS and VSM in detail. The results indicated that magnetic graphene@PANI was completely covered by porous TiO 2 with random orientations and the saturation magnetization value of the composite was 19.2 emu g À1 . PANI was used to decrease the absorber thickness, while the porous TiO 2 with a large surface area was designed to enhance the interaction between the electromagnetic (EM) wave and the absorber through multiple reflections, thus enhancing EM wave absorption properties. As an EM wave absorber, the maximum reflection loss of the composite was up to À45.4 dB due to the better normalized characteristic impedance (close to 1) at a thickness of only 1.5 mm and the absorption bandwidths exceeding À10 dB were 11.5 GHz when the thickness ranged from 1 to 3.5 mm. The excellent EM wave absorption performance was ascribed to the combined contribution from the enhanced dielectric relaxation processes, the unique porous nanostructures, the quarter-wave length matching model and the well-matched normalized characteristic impedance. Consequently, it is believed that the composite could be used as an excellent EM wave absorption material and the two-step strategy offered an effective way to design a high-performance EM wave absorber with a relatively thin thickness.

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“…Generally, an ideal EM absorber should satisfy the requirements of light weight, strong absorption, wide absorption frequency range, and thin matching thickness. Depending on the attenuation mechanisms, the EM absorption materials can be mainly classified into two types: one is magnetic loss materials such as Fe [13], Co [14,15], Ni [16,17], and ferrites [1,3], while another is dielectric loss materials including CNTs [18], CuS [19], ZnO [20], and TiO 2 [21]. However, it is not facile to achieve impedance matching relying solely on dielectric loss or magnetic loss according to Z in = Z 0 (μ r /ε r ) 1/2 [22].…”

Section: Introductionmentioning

confidence: 99%

Strengthened electromagnetic absorption performance derived from synergistic effect of carbon nanotube hybrid with Co@C beads

Qiao

Liu

et al. 2017

Adv Compos Hybrid Mater

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The composite structure of Co beads (200-300 nm) threaded by carbon nanotubes has been synthesized through a facile solvothermal method followed by a carbon reduction process. A carbon layer of ca. 5 nm was coated on the surface of Co beads to form a coreshell structure (CNTs/Co@C), in favor of the antioxidation of Co nanoparticles. The CNTs/Co@C hybrid showed a saturation magnetization (M s ) of 82.5 emu g −1 and a larger H c value of 258.8 Oe than bulk Co (ca. 10 Oe). Served as an EM wave absorption material, the epoxy resin composites consisting of 60 wt% and 40 wt% CNTs/Co@C hybrid exhibited effective EM absorption (RL < − 10 dB) over the frequency ranges of 1.5-15 and 1.6-20 GHz with the matching thicknesses of 1.0-7.5 and 1.0-10.0 mm, respectively. The superior EM absorption performances of CNTs/Co@C hybrid containing strong absorption, wide frequency range, thin thickness, and light weight are mainly attributed to the synergy of magnetic loss from Co beads and dielectric loss from carbon nanotubes, as well as remarkable impedance matching.

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Construction of CuS Nanoflakes Vertically Aligned on Magnetically Decorated Graphene and Their Enhanced Microwave Absorption Properties

Cited by 437 publications

References 68 publications

Room-Temperature High-Performance H₂S Sensor Based on Porous CuO Nanosheets Prepared by Hydrothermal Method

Room-Temperature High-Performance H₂S Sensor Based on Porous CuO Nanosheets Prepared by Hydrothermal Method

Magnetic graphene@PANI@porous TiO₂ ternary composites for high-performance electromagnetic wave absorption

Strengthened electromagnetic absorption performance derived from synergistic effect of carbon nanotube hybrid with Co@C beads

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Construction of CuS Nanoflakes Vertically Aligned on Magnetically Decorated Graphene and Their Enhanced Microwave Absorption Properties

Cited by 437 publications

References 68 publications

Room-Temperature High-Performance H2S Sensor Based on Porous CuO Nanosheets Prepared by Hydrothermal Method

Room-Temperature High-Performance H2S Sensor Based on Porous CuO Nanosheets Prepared by Hydrothermal Method

Magnetic graphene@PANI@porous TiO2 ternary composites for high-performance electromagnetic wave absorption

Strengthened electromagnetic absorption performance derived from synergistic effect of carbon nanotube hybrid with Co@C beads

Contact Info

Product

Resources

About

Room-Temperature High-Performance H₂S Sensor Based on Porous CuO Nanosheets Prepared by Hydrothermal Method

Room-Temperature High-Performance H₂S Sensor Based on Porous CuO Nanosheets Prepared by Hydrothermal Method

Magnetic graphene@PANI@porous TiO₂ ternary composites for high-performance electromagnetic wave absorption