Asymmetric Carbon Nanohorn Enabled Soft Capacitors with High Power Density and Ultra‐Low Cutoff Frequency

Li, Benxuan; Zhan, Shijie; Wang, Haolan; Hou, Bo; Amaratunga, G.A.J.

doi:10.1002/admt.202000372

Cited by 5 publications

(3 citation statements)

References 73 publications

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“…Nanocarbon materials are becoming increasingly popular due to their remarkable physicochemical attributes, such as high surface area, good aspect ratio, superlative conductivity, impressive mechanical strength, outstanding thermal stability, and chemical inertness. − With these exceptional functional capabilities, this class of materials also showcases a wide range of dimensional variations, including fullerene, carbon nanohorn, , carbon nanotube, , graphene, − and graphitized nanofiber (GNF), , making them versatile for a broad spectrum of applications in emerging fields such as sensing, catalysis, environmental remediation, water generation, energy storage, and superconductors . An especially exciting attribute of nanocarbon materials is their ability to be assembled into three-dimensional (3D) nanocarbon aerogels through a variety of methods (e.g., hydrothermal method and polymer-assisted cross-linking method) to create highly porous and ultralight-weight bulk materials …”

Section: Introductionmentioning

confidence: 99%

Density-Induced Joule-Heating Characteristics of Nanocarbon Aerogels: Implications for Tunable Electrothermal Behaviors

Xia

Shen

et al. 2023

ACS Appl. Nano Mater.

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An in-depth understanding of the electrothermal characteristics and behaviors of nanocarbon aerogels is crucial for optimizing their Joule-heating performance and expanding their applications. Modifying a single parameter of nanocarbon aerogels can reveal potential variations in Joule heating, which makes it a valuable area for investigation. This study explores reduced graphene oxide aerogels and reduced graphitized nanofiber aerogels with varying densities (14.9–31.7 mg·cm–3), fabricated using the hydrothermal method and polymer-assisted cross-linking method, to elucidate density-induced Joule-heating discrepancies. The critical step in aerogel preparation is the freeze-drying process, which yields structurally intact nanocarbon aerogels for Joule-heating experiments. Aerogels with higher densities displayed enhanced electrical and thermal conductivities (up to 24.9 S·m–1 and 0.882 W·m–1·K–1, respectively) compared to their lower-density counterparts, owing to the increased number of pathways available for electron/phonon transportation. The low-density aerogels exhibited more pronounced features in the heating temperature range (up to 117 °C) and efficiency (up to 46.5 °C·W–1), making them more suitable for energy-efficient applications. Despite variations in the density, all of the fabricated aerogels showed efficient electron hopping between the interconnected nanocarbons, which enabled uniform resistive heating throughout the aerogel entity. This work highlighted the importance of density control in altering the Joule-heating performance of nanocarbon aerogels for specific applications, which has far-reaching implications for optimizing the properties of other electrically conducting aerogel materials.

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Section: Introductionmentioning

confidence: 99%

Density-Induced Joule-Heating Characteristics of Nanocarbon Aerogels: Implications for Tunable Electrothermal Behaviors

Xia

Shen

et al. 2023

ACS Appl. Nano Mater.

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“…The conductive agent used to secure electrical conducting pathways in a silicon electrode may be also exploited as a buffer phase to suppress dimensional changes upon repeated lithiation and delithiation. However, nano-sized carbon black particles, which conventionally used conductive agents for silicon electrodes, cannot maintain the electrical pathways and the initial microstructures of silicon electrodes against the volume expansion of silicon during cycling. , Although a lot of carbon materials with various nanostructures as conductive agents for lithium-ion batteries have been reported, − to the best of our knowledge, few reports have been published on conductive agents that can act as physical buffers in silicon electrodes. Given that the science and technology of carbon materials has flourished in recent decades, − it is likely that a variety of nanostructured carbon materials can offset mechanical and electrical degradation of silicon electrodes associated with volume changes of silicon during cycling.…”

Section: Introductionmentioning

confidence: 99%

Hollow Graphene as an Expansion-Inhibiting Electrical Interconnector for Silicon Electrodes in Lithium-Ion Batteries

Park

Kim

et al. 2021

ACS Appl. Mater. Interfaces

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Huge volume changes of silicon particles upon alloying and dealloying reactions with lithium are a major reason for the poor cycle performance of silicon-based anodes for lithium-ion batteries. To suppress dimensional changes of silicon is a key strategy in attempts to improve the electrochemical performance of silicon-based anodes. Here, we demonstrate that a conductive agent can be exploited to offset the mechanical strain imposed on silicon electrodes caused by volume expansion of silicon associated with lithiation. Hollow graphene particles as a conductive agent inhibit volume expansion by absorbing the swelling of silicon upon lithiation through flattening the free voids surrounded by the graphene shell. As a result, silicon electrodes with hollow graphene showed a height expansion of 20.4% after full lithiation with a capacity retention of 69% after 200 cycles, while the silicon electrode with conventional carbon black showed an expansion of 76.8% under the same conditions with a capacity retention of 38%. Some of the deflated hollow graphene returns to its initial shape on delithiation due to the mechanical flexibility of the graphene shell layer. Such a robust microstructure of a silicon electrode incorporating hollow graphene that serves as both an expansion inhibitor and a conductive agent greatly improves capacity retention compared with silicon electrodes with the conventionally used carbon black.

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“…Carbon dots have been used in various aspects, including cell imaging 6 , fluorescent ink 7 , photocatalysis [8][9] , drug delivery 10 , ion detection [11][12][13][14][15][16][17] , energy storage 18 and optoelectronics 19 . However, the lower fluorescence quantum yields and the singleness of CQDs sensors have limited their practical applications.…”

Section: Introduction：mentioning

confidence: 99%

Eu³⁺-functionalized CQD hybrid material: synthesis, luminescence properties and sensing application for the detection of Cu²⁺

Liú

Wang

et al. 2021

Mater. Adv.

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Asymmetric Carbon Nanohorn Enabled Soft Capacitors with High Power Density and Ultra‐Low Cutoff Frequency

Cited by 5 publications

References 73 publications

Density-Induced Joule-Heating Characteristics of Nanocarbon Aerogels: Implications for Tunable Electrothermal Behaviors

Density-Induced Joule-Heating Characteristics of Nanocarbon Aerogels: Implications for Tunable Electrothermal Behaviors

Hollow Graphene as an Expansion-Inhibiting Electrical Interconnector for Silicon Electrodes in Lithium-Ion Batteries

Eu³⁺-functionalized CQD hybrid material: synthesis, luminescence properties and sensing application for the detection of Cu²⁺

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Asymmetric Carbon Nanohorn Enabled Soft Capacitors with High Power Density and Ultra‐Low Cutoff Frequency

Cited by 5 publications

References 73 publications

Density-Induced Joule-Heating Characteristics of Nanocarbon Aerogels: Implications for Tunable Electrothermal Behaviors

Density-Induced Joule-Heating Characteristics of Nanocarbon Aerogels: Implications for Tunable Electrothermal Behaviors

Hollow Graphene as an Expansion-Inhibiting Electrical Interconnector for Silicon Electrodes in Lithium-Ion Batteries

Eu3+-functionalized CQD hybrid material: synthesis, luminescence properties and sensing application for the detection of Cu2+

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Product

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Eu³⁺-functionalized CQD hybrid material: synthesis, luminescence properties and sensing application for the detection of Cu²⁺