Carbon carrier-based rapid Joule heating technology: a review on the preparation and applications of functional nanomaterials

Ding, Xinrui; He, Zihan; Li, Jiasheng; Xu, Xiaolin; Li, Zongtao

doi:10.1039/d4nr01510j

Nanoscale

2024

DOI: 10.1039/d4nr01510j

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Carbon carrier-based rapid Joule heating technology: a review on the preparation and applications of functional nanomaterials

Xinrui Ding,

Zihan He,

Jiasheng Li

et al.

Abstract: Compared to conventional heating techniques, the carbon carrier-based rapid Joule heating (CJH) method is a new technology with an extremely high heating rate and ultra-high temperature. Therefore, CJH technology has...

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Cited by 4 publications

References 178 publications

(334 reference statements)

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Synthetic nanoarchitectonics with ultrafast Joule heating of graphene-based electrodes for high energy density supercapacitor application

Mathan,

Selvaraj,

Assiri

et al. 2024

Surfaces and Interfaces

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Synthetic nanoarchitectonics with ultrafast Joule heating of graphene-based electrodes for high energy density supercapacitor application

Mathan,

Selvaraj,

Assiri

et al. 2024

Surfaces and Interfaces

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Design and Application of Joule Heating Processes for Decarbonized Chemical and Advanced Material Synthesis

Griffin,

Robertson,

Gunter

et al. 2024

Ind. Eng. Chem. Res.

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Atmospheric CO 2 concentrations keep increasing at intensifying rates due to rising energy and material demands. The chemical production industry is a large energy consumer, responsible for up to 935 Mt of CO 2 emissions per year, and decarbonization is its major goal moving forward. One of the primary sources of energy consumption and CO 2 emissions in the chemical sector is associated with the production and use of heat for material synthesis, which conventionally was generated through the combustion of fossil fuels. To address this grand challenge, Joule heating has emerged as an alternative heating method that greatly increases process efficiency, reducing both energy consumption and greenhouse gas emissions. In this Review, we discuss the key concepts that govern these Joule heating processes including material selection and reactor design, as well as the current state-of-the-art in the literature for employing these processes to synthesize commodity chemicals along with advanced materials such as graphene, metal species, and metal carbides. Finally, we provide a perspective on future research avenues within this field, which can facilitate the widespread adoption of Joule heating for decarbonizing industrial processes.

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Ultrafast Joule Heating Modification of Methane-Pyrolyzed Carbon Black for Supercapacitor Application

He,

Shen,

Liu

2024

Langmuir

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Carbon black from methane pyrolysis for hydrogen is an alternative resource and can be improved for conductive material supplication. Our current work uses an ultrafast Joule heating technique to modify the methane-pyrolyzed carbon black and prepare nanoparticles of electrode material for supercapacitor application, coupled with density functional theory, structural, and electrochemical analyses. Evolution rules of the carbon and pore structures of the modified sample with an increase in temperature reveal good structure improvements. The graphitization degree of modified carbon black nanoparticles increases, and the particle morphology changes from a smooth surface, disordered structure removal, and pore formation to graphite crystallization. Band structure and state density analytical results show that the modified carbon black with a defect-free structure possesses metallic properties and exhibits good electrical conductivity. A temperature around 1576 °C to the initial graphitization was defined based on the critical point of the evolution of ordered and disordered structures, while the electrical conductivity of the carbon black nanoparticles at 2000 °C reaches 2300 S/m. The modified carbon black performed with stable charge/discharge characteristics, exhibiting a 4.31% capacitance drop at a current load of 2 A/g and a 18.31% capacitance drop at a current load of 20 A/g.

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Carbon carrier-based rapid Joule heating technology: a review on the preparation and applications of functional nanomaterials

Abstract: Compared to conventional heating techniques, the carbon carrier-based rapid Joule heating (CJH) method is a new technology with an extremely high heating rate and ultra-high temperature. Therefore, CJH technology has...

Cited by 4 publications

References 178 publications

Synthetic nanoarchitectonics with ultrafast Joule heating of graphene-based electrodes for high energy density supercapacitor application

Synthetic nanoarchitectonics with ultrafast Joule heating of graphene-based electrodes for high energy density supercapacitor application

Design and Application of Joule Heating Processes for Decarbonized Chemical and Advanced Material Synthesis

Ultrafast Joule Heating Modification of Methane-Pyrolyzed Carbon Black for Supercapacitor Application

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