Skein-shaped ZnO/N-doped carbon microstructures as a high performance anode material for lithium-ion batteries

Kim, Hyeong-Su; Jae, Woojin; Song, Jungwook; Kim, Jongsik

doi:10.1016/j.jallcom.2018.09.198

Cited by 43 publications

(9 citation statements)

References 60 publications

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“…They can form organic substrates with certain –OH and –NH 2 groups, and constitute metal ligand complexes with Cu 2+ coordination. 38 After high-temperature carbonization under a N 2 atmosphere, carbon-coated copper and trace nickel composites were constructed. The carbon protective layer formed in this step can prevent the structural collapse of the MOF during the next phosphorization step.…”

Section: Resultsmentioning

confidence: 99%

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MOF-derived carbon coated Cu₃P with Ni doping as advanced supercapacitor electrode materials

Jin

Jia

et al. 2022

Sustainable Energy Fuels

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Section: Resultsmentioning

confidence: 99%

“…H 3 BTC and PVP are carbon and nitrogen sources of the products, respectively. They can form organic substrates with certain -OH and -NH 2 groups, and constitute metal ligand complexes with Cu 2+ coordination 38. Aer high-temperature carbonization under a N 2 atmosphere, carbon-coated copper and trace nickel composites were constructed.…”

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confidence: 99%

MOF-derived carbon coated Cu₃P with Ni doping as advanced supercapacitor electrode materials

Jin

Jia

et al. 2022

Sustainable Energy Fuels

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“…The ZnO-rG CMs promise better results due to the good properties of graphene. ZnO/G 516 100 [35] ZnO/GN 1100 100 [50] AZO/G 391 100 [49] ZnO/G 360 200 [76] ZnO/G 550 100 [77] ZnO/G 560 100 [78] ZnO/G 300 50 [79] ZnO/CN 1047 100 [80] ZnO/G 749 100 [81] ZnO/G 550 100 [82] Cu/ZnO/G 630 100 [83] ZnO/C 520 100 [84] ZnO/CN 1177 100 [85] ZnO/NSG 720 100 [73] NC = nitrided carbon; G = graphene; NG = nitrided graphene; NSG = nitrided-sulfurized graphene. and graphene, of which graphene, in this case, is reduced with nitrogen and showed a very remarkable reversible capacity, comparing it with other results.…”

Section: Composite Zno-graphene Materialsmentioning

confidence: 99%

Anodic ZnO-Graphene Composite Materials in Lithium Batteries

Herrera-Pérez¹,

Pérez-Zúñiga²,

Verde-Gómez³

et al. 2019

Zinc Oxide Based Nano Materials and Devices

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An important area to cope with in the implementation of technologies for the generation of energy from renewable sources is storage, so it is a priority to develop new ways of storing energy with high efficiency and storage capacity. Experimental reports focused on ZnO-graphene composite materials applied to the anode design which indicated that they show low efficiencies of around 50 %, but values very close to the theoretical capacity have already been reported in recent years. The low efficiency of the materials for the anode design of the Li-ion battery is mainly attributed to the pulverization and fragmentation of the material or materials, caused by the volumetric changes and stability problems during the charge/discharge cycles. In this chapter, we will discuss the development of composite materials such as ZnOgraphene in its application for the design of the anode in the Li-ion battery.

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Section: Composite Zno-graphene Materialsmentioning

confidence: 99%

Zinc Oxide Based Nano Materials and Devices

Nahhas¹

2019

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received his PhD degree in Electrical Engineering (Electronics) from the University of Pittsburgh, PA, USA, in 2001. He has served in many prestigious leadership positions, including as the dean of the College of Engineering, the head of the Department, and the vice dean. He is currently with the College of Engineering and Islamic Architecture, Umm Al-Qura University. He has participated in reviewing several academic articles and dissertations in the area of electrical and electronic communications. His current research interests include developing new photonic and electronic devices at nanoscales involving various functional materials, such as wide-bandgap semiconductors, nanostructured materials, and fabrication of ZnO and GaN optical devices. Prof. Nahhas received his first patent in 2016 from the United States and is an official reviewer of several journals. ContentsPreface XIII Section 1 IntroductionChapter 1 Introductory Chapter: Overview of ZnO Based Nano Materials and Devices by Ahmed M. Nahhas Section 2 ZnO Nanostructures Chapter 2 Structural and Luminescence Properties of ZnO Nanoparticles Synthesized by Mixture of Fuel Approach in Solution Combustion Method

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Skein-shaped ZnO/N-doped carbon microstructures as a high performance anode material for lithium-ion batteries

Cited by 43 publications

References 60 publications

MOF-derived carbon coated Cu₃P with Ni doping as advanced supercapacitor electrode materials

MOF-derived carbon coated Cu₃P with Ni doping as advanced supercapacitor electrode materials

Anodic ZnO-Graphene Composite Materials in Lithium Batteries

Zinc Oxide Based Nano Materials and Devices

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Skein-shaped ZnO/N-doped carbon microstructures as a high performance anode material for lithium-ion batteries

Cited by 43 publications

References 60 publications

MOF-derived carbon coated Cu3P with Ni doping as advanced supercapacitor electrode materials

MOF-derived carbon coated Cu3P with Ni doping as advanced supercapacitor electrode materials

Anodic ZnO-Graphene Composite Materials in Lithium Batteries

Zinc Oxide Based Nano Materials and Devices

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MOF-derived carbon coated Cu₃P with Ni doping as advanced supercapacitor electrode materials

MOF-derived carbon coated Cu₃P with Ni doping as advanced supercapacitor electrode materials