Graphene-reinforced polymeric nanocomposites in computer and electronics industries

KardanMoghaddam, Hossein; Maraki, MohamadReza; Rajaei, Amir

doi:10.2298/fuee2003351m

Cited by 8 publications

(3 citation statements)

References 97 publications

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“…When graphene is introduced to pure nickel thin film, the electrical conductivity of nickel and its compounds increases by 15%. (KardanMoghaddam et al 2020 ); on the other hand, adding graphene oxide (GO) to the electrodeposition bath, it was possible to significantly increase the electrical conductivity of the nickel thin film produced by jet electrodeposition. Furthermore, it was discovered that the electrical conductivity of the resulting thin film increased as the concentration of GO increased in the electrolysis bath (Ji et al 2018 ).…”

Section: Introductionmentioning

confidence: 99%

Green hydrogen generation in alkaline solution using electrodeposited Ni-Co-nano-graphene thin film cathode

Shaarawy,

Hussein,

Attia

et al. 2024

Environ Sci Pollut Res

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Green hydrogen generation technologies are currently the most pressing worldwide issues, offering promising alternatives to existing fossil fuels that endanger the globe with growing global warming. The current research focuses on the creation of green hydrogen in alkaline electrolytes utilizing a Ni-Co-nano-graphene thin film cathode with a low overvoltage. The recommended conditions for creating the target cathode were studied by electrodepositing a thin Ni-Co-nano-graphene film in a glycinate bath over an iron surface coated with a thin copper interlayer. Using a scanning electron microscope (SEM) and energy-dispersive X-ray (EDX) mapping analysis, the obtained electrode is physically and chemically characterized. These tests confirm that Ni, Co, and nano-graphene are homogeneously dispersed, resulting in a lower electrolysis voltage in green hydrogen generation. Tafel plots obtained to analyze electrode stability revealed that the Ni-Co-nano-graphene cathode was directed to the noble direction, with the lowest corrosion rate. The Ni-Co-nano-graphene generated was used to generate green hydrogen in a 25% KOH solution. For the production of 1 kg of green hydrogen utilizing Ni-Co-nano-graphene electrode, the electrolysis efficiency was 95.6% with a power consumption of 52 kwt h−1, whereas it was 56.212. kwt h−1 for pure nickel thin film cathode and 54. kwt h−1 for nickel cobalt thin film cathode, respectively.

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Section: Introductionmentioning

confidence: 99%

Green hydrogen generation in alkaline solution using electrodeposited Ni-Co-nano-graphene thin film cathode

Shaarawy,

Hussein,

Attia

et al. 2024

Environ Sci Pollut Res

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“…Graphene, a honeycomb-like sheet of carbon that is only one atom thick, has attracted much attention for several years due to its special configuration and capability, and it is considered a promising reinforcing particle [ 23 , 24 , 25 , 26 ]. However, the homogeneous dispersion of graphene in electrolytes and the electrodeposition of high-performance composite coatings remains a technical challenge due to the high active surface area [ 27 ].…”

Section: Introductionmentioning

confidence: 99%

Preparation and Properties of Electrodeposited Ni-B-Graphene Oxide Composite Coatings

et al. 2022

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With the rapid development of modern industries, the surface quality and performance of metals need to be improved. Composite electrodeposition (co-deposition) has evolved as an important technique for improving the surface performance of metal materials. Herein, a new type of graphene oxide (GO)-reinforced nickel–boron (Ni-B) composite coating was successfully prepared on a 7075 aluminum (Al) alloy by co-deposition. Characterization revealed a significant improvement in the mechanical and anti-corrosion properties of the composite with the incorporation of GOs. The composite showed a rougher, compact, cauliflower-like morphology with finer grains, a higher hardness (1532 HV), a lower rate of wear (5.20 × 10−5 mm3∙N−1∙m−1), and a lower corrosion rate (33.66 × 10−3 mm∙y−1) compared with the Ni-B alloy deposit (878 HV, 9.64 × 10−5 mm3∙N−1∙m−1, and 116.64 × 10−3 mm∙y−1, respectively). The mechanism by which GOs strengthen the Ni-B matrix is discussed.

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“…Graphene, a one‐atom thick honeycomb‐like sheet of carbon, has caught the attention of researchers in the field of material physics and engineering due to its excellent mechanical, electrical, optical, and thermal properties. [ 26–29 ] Ni‐graphene and nickel‐based alloy‐graphene composite coatings have been successfully obtained by co‐deposition, with the presence of graphene nanoplatelets (GNPs) enhancing the coating microhardness, friction and wear resistance, and anti‐corrosion properties. [ 30–33 ] However, few studies have been undertaken on the electrodeposition of Ni–W/GNPs.…”

Section: Introductionmentioning

confidence: 99%

Preparation and Properties of Ni–W Composite Coatings Reinforced by Graphene Nanoplatelets

et al. 2021

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Metal enhancement is crucial for reducing energy use and material waste. Composite electrodeposition is an economic and efficient method for improving the surface properties of metals. Herein, Ni–W matrix composite coatings reinforced with graphene nanoplatelets (GNPs) are prepared on 7075 aluminum (Al) alloy plates by the co‐deposition technique. Characterization results reveal that the mechanical properties and corrosion resistance of the coating can be improved by the successful embedding of GNPs. The Ni–W/GNP coating exhibits rougher, cauliflower‐like morphology, higher microhardness (782.6 HV), lower wear rate (2.72 × 10−5 mm3 N−1 m−1), and better corrosion current density (18.19 μA cm−2) compared with the Ni–W coating (578.2 HV, 7.43 × 10−5 mm3 N−1 m−1, and 25.16 μA cm−2, respectively). Moreover, X‐ray diffraction (XRD) spectroscopy and analysis verify that the grain size is decreased for GNP‐reinforced composite coatings with a typical Ni‐based solid‐solution phase.

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Graphene-reinforced polymeric nanocomposites in computer and electronics industries

Cited by 8 publications

References 97 publications

Green hydrogen generation in alkaline solution using electrodeposited Ni-Co-nano-graphene thin film cathode

Green hydrogen generation in alkaline solution using electrodeposited Ni-Co-nano-graphene thin film cathode

Preparation and Properties of Electrodeposited Ni-B-Graphene Oxide Composite Coatings

Preparation and Properties of Ni–W Composite Coatings Reinforced by Graphene Nanoplatelets

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