Heater‐Free and Substrate‐Independent Growth of Vertically Standing Graphene Using A High‐Flux Plasma‐Enhanced Chemical Vapor Deposition

Wu, Zhiheng; Zhang, Yongshang; Shen, Yonglong; Zhang, Wei; Shao, Guosheng

doi:10.1002/admi.202000854

Cited by 10 publications

(14 citation statements)

References 54 publications

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“…A way forward lies in significant enlargement in the specific interfacial area with electrocatalysts, so that Li 2 S could be spread over a large surface to reduce overall film thickness and avoid local aggregation. Conducting two‐dimensional (2D) materials such as low‐defect graphene would be an additive material of choice, so that its effective coupling with nanoelectrocatalysts could enable the best use of the surficial area of the catalysts while providing an electric highway for charge and ion transportation 17,46–50 …”

Section: Introductionmentioning

confidence: 99%

A flexible metallic TiC nanofiber/vertical graphene 1D/2D heterostructured as active electrocatalyst for advanced Li–S batteries

Zhang

et al. 2021

InfoMat

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172

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The realistic application of lithium–sulfur (Li–S) batteries has been severely hindered by the sluggish conversion kinetics of polysulfides (LiPS) and inhomogeneous deposition of Li2S at high sulfur loading and low electrolyte/sulfur ratio (E/S). Herein, a flexible Li–S battery architecture based on electrocatalyzed cathodes made of interfacial engineered TiC nanofibers and in situ grown vertical graphene are developed. Integrated 1D/2D heterostructured electrocatalysts are realized to enable highly improved Li+ and electron transportation together with significantly enhanced affinity to LiPS, which effectively accelerate the conversion kinetics between sulfur species, and thus induce homogeneous deposition of Li2S in the catalyzed cathodes. Consequently, highly active electro‐electrocatalysts‐based cells exhibit remarkable rate capability at 2C with a high specific capacity of 971 mAh g−1. Even at ultra‐high sulfur loading and low E/S ratio, the battery still delivers a high areal capacity of 9.1 mAh cm−2, with a flexible pouch cell being demonstrated to power a LED array at different bending angles with a high capacity over 100 cycles. This work puts forward a novel pathway for the rational design of effective nanofiber electrocatalysts for cathodes of high‐performance Li–S batteries.

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Section: Introductionmentioning

confidence: 99%

A flexible metallic TiC nanofiber/vertical graphene 1D/2D heterostructured as active electrocatalyst for advanced Li–S batteries

Zhang

et al. 2021

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172

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“…[15,30,31] Our previous work has demonstrated the potential application of vertically standing graphene films (VSG) directly as the anode in a sodium-ion battery. [22] In order to obtain defective, porous, and vertically aligned graphene nanosheets with a compact arrangement for an enhancement of sodium storage capability, we introduced and modulate the nitrogen plasma via varying the nitrogen gas flow rate from 0 sccm to 10 sccm during the fabrication process in our laboratory-built H-PECVD system, as shown in step 1 in Figure 1a. The fabricated NVG shows apparently different morphology as seen in Figure S1.…”

Section: Resultsmentioning

confidence: 99%

“…pathway of ions; thus, it has been introduced as support backbone for active materials [18][19][20] or directly used as anode for batteries. [21,22] However, the defective and porous structure with large specific surface area (SSA) of these carbon materials always suffer from extremely low initial Coulombic efficiency (ICE), low reversible capacity, and unsatisfied cycling stability due to uncontrollable decomposition of the electrolyte and poor interface construction between electrolyte and electrode. [23,24] Therefore, it is highly desired to deactivate the surface defects while maintain the sodium storage capacity of vertically oriented structure.…”

Section: Introductionmentioning

confidence: 99%

Atomic Layer Coated Al₂O₃ on Nitrogen Doped Vertical Graphene Nanosheets for High Performance Sodium Ion Batteries

Zhang

Deng

et al. 2021

Energy & Environ Materials

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Heteroatom doped graphene materials are considered as promising anode for high‐performance sodium‐ion batteries (SIBs). Defective and porous structure especially with large specific surface area is generally considered as a feasible strategy to boost reaction kinetics; however, the unwanted side reaction at the anode hinders the practical application of SIBs. In this work, a precisely controlled Al2O3 coated nitrogen doped vertical graphene nanosheets (NVG) anode material has been proposed, which exhibits excellent sodium storage capacity and cycling stability. The ultrathin Al2O3 coating on the NVG is considered to help construct an advantageous interface between electrode and electrolyte, both alleviating the electrolyte decomposition and enhancing sodium adsorption ability. As a result, the optimal Al2O3 coated NVG materials delivers a high reversible capacity (835.0 mAh g−1) and superior cycling stability (retention of 92.3% after 5000 cycles). This work demonstrates a new way to design graphene‐based anode materials for high‐performance sodium‐ion batteries.

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“…VFLG can be prepared on different substrates with or without catalysts at a low temperature through plasma-enhanced chemical vapor deposition (PECVD) [ 10 , 11 , 12 , 13 , 14 ]. The impact factors of VFLG growth, such as plasma power, gas ratio, pressure, growth time, temperature and so on, have been studied in detail for the controllable growth of VFLG regarding growth rate, morphology and density of VFLG [ 15 , 16 , 17 , 18 ].…”

Section: Introductionmentioning

confidence: 99%

Effects of Substrates on Nucleation, Growth and Electrical Property of Vertical Few-Layer Graphene

et al. 2022

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A key common problem for vertical few-layer graphene (VFLG) applications in electronic devices is the solution to grow on substrates. In this study, four kinds of substrates (silicon, stainless-steel, quartz and carbon-cloth) were examined to understand the mechanism of the nucleation and growth of VFLG by using the inductively-coupled plasma-enhanced chemical vapor deposition (ICPCVD) method. The theoretical and experimental results show that the initial nucleation of VFLG was influenced by the properties of the substrates. Surface energy and catalysis of substrates had a significant effect on controlling nucleation density and nucleation rate of VFLG at the initial growth stage. The quality of the VFLG sheet rarely had a relationship with this kind of substrate and was prone to being influenced by growth conditions. The characterization of conductivity and field emissions for a single VFLG were examined in order to understand the influence of substrates on the electrical property. The results showed that there was little difference in the conductivity of the VFLG sheet grown on the four substrates, while the interfacial contact resistance of VFLG on the four substrates showed a tremendous difference due to the different properties of said substrates. Therefore, the field emission characterization of the VFLG sheet grown on stainless-steel substrate was the best, with the maximum emission current of 35 µA at a 160 V/μm electrostatic field. This finding highlights the controllable interface of between VFLG and substrates as an important issue for electrical application.

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Heater‐Free and Substrate‐Independent Growth of Vertically Standing Graphene Using A High‐Flux Plasma‐Enhanced Chemical Vapor Deposition

Cited by 10 publications

References 54 publications

A flexible metallic TiC nanofiber/vertical graphene 1D/2D heterostructured as active electrocatalyst for advanced Li–S batteries

A flexible metallic TiC nanofiber/vertical graphene 1D/2D heterostructured as active electrocatalyst for advanced Li–S batteries

Atomic Layer Coated Al₂O₃ on Nitrogen Doped Vertical Graphene Nanosheets for High Performance Sodium Ion Batteries

Effects of Substrates on Nucleation, Growth and Electrical Property of Vertical Few-Layer Graphene

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Heater‐Free and Substrate‐Independent Growth of Vertically Standing Graphene Using A High‐Flux Plasma‐Enhanced Chemical Vapor Deposition

Cited by 10 publications

References 54 publications

A flexible metallic TiC nanofiber/vertical graphene 1D/2D heterostructured as active electrocatalyst for advanced Li–S batteries

A flexible metallic TiC nanofiber/vertical graphene 1D/2D heterostructured as active electrocatalyst for advanced Li–S batteries

Atomic Layer Coated Al2O3 on Nitrogen Doped Vertical Graphene Nanosheets for High Performance Sodium Ion Batteries

Effects of Substrates on Nucleation, Growth and Electrical Property of Vertical Few-Layer Graphene

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Atomic Layer Coated Al₂O₃ on Nitrogen Doped Vertical Graphene Nanosheets for High Performance Sodium Ion Batteries