3D Graphene Fibers Grown by Thermal Chemical Vapor Deposition

Zeng, Jie; Ji, Xiulin; Ma, Yihui; Zhang, Zhongxing; Wang, Shuguang; Ren, Zhonghua; Chen, Zhi; Yu, Jie

doi:10.1002/adma.201705380

Cited by 132 publications

(93 citation statements)

References 58 publications

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“…[35] The presence of the 2D peak is evidence for the formation of stacked layers of graphene. [36] With increasing laser power from 3.0% to 5.5%, I D /I G ratio decreases first and reaches a minimum of 0.398 at the laser power of 4.5% ( Figure 1C). When laser power increases from 5.0% to 5.5%, the I D /I G ratio increases, which suggests that at these high powers, the CNS-LSG is destroyed by laser.…”

Section: Supercapacitorsmentioning

confidence: 94%

“…The Raman spectra show three main peaks: G peak around 1580 cm −1 which is commonly assigned to graphitic carbon, D peak around 1350 cm −1 which results from lattice defects and 2D peak an overtone generally present at 2700 cm −1 . The presence of the 2D peak is evidence for the formation of stacked layers of graphene . With increasing laser power from 3.0% to 5.5%, I D / I G ratio decreases first and reaches a minimum of 0.398 at the laser power of 4.5% (Figure C).…”

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confidence: 94%

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3D Laser Scribed Graphene Derived from Carbon Nanospheres: An Ultrahigh‐Power Electrode for Supercapacitors

et al. 2019

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Laser scribed graphene (LSG) electrodes hold great potential as supercapacitor electrodes. However, the rate performance of LSGs has been limited by the micropore‐dominated electrode structure. Here, a new method is proposed to prepare LSG electrodes with a 3D porous framework dominated by meso‐ and macro‐pores, a property that enables exceptional rate performance. The process uses amorphous carbon nanospheres (CNS) as precursors, which, after laser scribing, are transformed into highly turbostratic graphitic carbon electrodes (henceforth denoted as CNS‐LSG) with a 3D framework structure dominated by meso‐ and macro‐pores. When used as electrodes in conventional supercapacitor devices, the CNS‐LSG electrodes exhibit a high volumetric power density of 28 W cm−3, which is 28 times higher than that of current commercial activated carbon supercapacitors, and is the highest among all the reported laser scribed/induced graphene electrodes.

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Section: Supercapacitorsmentioning

confidence: 94%

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confidence: 94%

3D Laser Scribed Graphene Derived from Carbon Nanospheres: An Ultrahigh‐Power Electrode for Supercapacitors

et al. 2019

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Section: Progress In the Application Of Gbfsmentioning

confidence: 99%

“…Flexible SCs based on the nonwoven fabric of improved GBFs exhibited a high areal capacitance of 1060 mF cm −2 and the capacitance could be further enhanced to 7398 mF cm −2 by overlaying serval layers of these fabrics. Alternatively, a 3D GBF assembly was obtained by vertically growing graphene nanosheet on carbon nanofibers via CVD (Figure g,h) and it featured high electrical conductivity (3.4 × 10 4 to 1.2 × 10 5 S m −1 ), rich nanosized pores and lightweight. These features ensure the 3D GBF assembly with an ultrahigh specific shielding effectiveness (SSE/ t ) of 60 932 dB cm 2 g −1 .…”

Section: Progress In the Application Of Gbfsmentioning

confidence: 99%

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Graphene‐Based Fibers: Recent Advances in Preparation and Application

Zhang

2019

Advanced Materials

109

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investigated [17][18][19][20] for building graphene-based fibers (GBFs) over recent years. [21][22][23] These unique macroscopic 1D assemblies of microscopic 2D graphene building blocks are of lightweight, high specific surface area (SSA), and remarkable mechanical and electrical properties, thus qualifying them as ideal materials for fiber electronics. [14,[24][25][26] Currently, the well-developed wet-spinning method is widely adopted in preparing GBFs, [27,28] while newly designed spinning methods with microfluidic spinnerets and different kinds of coagulation bath have yielded GBFs with novel structures and functions. Apart from these methods, emerging techniques such as chemical vapor deposition (CVD) and twisting have been developed to meet different applications of GBFs in strain sensors, stretchable SC, and multifunctional actuators. [9,29,30] Together with the evolution in their preparation, mechanical and electrical properties of GBFs have been considerably enhanced since their debut. Bioinspired strengthening and toughening strategies for membranes have been found to work for GBFs as well, and atomic doping methods have efficiently increased electrical conductivity of GBFs to a record value of 2.2 × 10 7 S m −1 , [31] which is even comparable to that of certain metals such as nickel (1.5 × 10 7 S m −1 ) and aluminum (3.5 × 10 7 S m −1 ). Based on their novel structures and significantly enhanced mechanical/electrical properties, GBFs have found their substantial uses particularly in newly designed, high-performance electrochemical devices for energy conversion and storage.Several excellent reviews have witnessed the rapid development of GBFs. [17,20,23] For example, Chou and co-workers [18] previously gave a comprehensive review on the synthesis, device performance, and potential applications of GBFs. Another review presented by Gao and his colleagues [32] focused on the microscopic mechanism during liquid crystal formation and summarized its effects on producing continuous fibers. Additionally, applications of GBFs in flexible/ wearable SCs and bioinspired nanocomposites were specifically discussed by Huang et al. [25] and Cheng and co-workers, [33] respectively. In this featured article, we mainly focus on very recent research advances in GBFs over the past few years and introduce progresses in preparation techniques, strategies for performance enhancement and novel applications (Figure 1), aiming to provide a state-of-the-art update for GBFs as well as perspectives for their future development.Graphene-based fibers (GBFs) are macroscopic 1D assemblies formed by using microscopic 2D graphene sheets as building blocks. Their unique structure exhibits the same merits as graphene such as low weight, high specific surface area, excellent mechanical/electrical properties, and ease of functionalization. Furthermore, the fibrous nature of GBFs is intrinsically compatible with existing textile technologies, making them suitable for applications in flexible and wearable electronics. Recently, novel synthetic ...

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