Fenton Reaction Doubled Biomass Carbon Activation Efficiency for High‐Performance Supercapacitors

Li, Yanyu; Ni, Lifeng; Luo, Jiayan; Zhu, Lulu; Zhang, Xiaoxiao; Li, Hongjie; Zada, Imran; Yu, Jin; Zhu, Shenmin; Lian, Keryn; Li, Yao; Zhang, Di

doi:10.1002/adfm.202403448

“…It represents an ecofriendly, cost-effective, and metal recycling technology, aligning with the principles of low-carbon initiatives. Leveraging the distinct and varied structural features of living organisms, biomass carbon materials obtained via the bioabsorption route exhibit unique and sophisticated structures, holding promise for enhanced electrochemical performance . Currently, there is a growing body of research focusing on the utilization of the bioabsorption method for fabricating electrode materials in batteries and supercapacitors.…”

Section: Introductionmentioning

confidence: 99%

“…Leveraging the distinct and varied structural features of living organisms, biomass carbon materials obtained via the bioabsorption route exhibit unique and sophisticated structures, holding promise for enhanced electrochemical performance. 12 Currently, there is a growing body of research focusing on the utilization of the bioabsorption method for fabricating electrode materials in batteries and supercapacitors. In our prior investigation, we explored the application of the bioabsorption method in both supercapacitors and batteries.…”

Section: Introductionmentioning

confidence: 99%

Utilizing Manganese Phase Transition in Bioabsorption Synthesis of MnO@Carbon Composites for Enhanced High-Performance Supercapacitors

Chen,

Zeng,

Wu

et al. 2024

ACS Sustainable Chem. Eng.

0

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The bioabsorption method has emerged as an innovative approach for synthesizing electrode materials, offering dual benefits of environmental pollution control and energy problem resolution. Existing literature lacks comprehensive investigation into the correlation between metal phase transitions and electrochemical performance throughout the material preparation process using the bioabsorption method, encompassing changes in metal valence states, crystal structures, and redox reactions. This study aims to establish a direct link between manganese phase transitions and electrochemical energy storage. It elucidates the enrichment mechanism and phase transition process induced by manganese stress on organisms. By employing phase diagram calculations and high-temperature potassium hydroxide assistance, MnO single-phase-doped biomass carbon electrode materials are successfully synthesized, enabling precise control over metal crystal phase transitions. The redox reactions involved in manganese electrochemical storage are elucidated. Specifically, the material exhibits a high specific surface area of 1, 234.088 m 2 •g −1 , a high degree of graphitization (I D /I G = 1.04), a specific capacitance of 498 F•g −1 at 0.5 A•g −1 , and a capacity retention of 94% after 25,000 cycles. This work delves into the manganese phase transition process to enhance electrochemical performance, offering insights into the accumulation mechanisms and biological phase transition under heavy metal stress and providing a foundation for designing electrode materials assisted by phase diagrams.

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Disorder Over Pore Size: Boosting Supercapacitor Efficiency

Zhang,

Wen

2024

Angewandte Chemie

0

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The urgent need for efficient energy storage systems has spotlighted supercapacitors and nanostructured porous carbon materials, which require structural optimization to enhance their performance and lifespan, necessitating advanced design and synthesis techniques. Recent research by Forse et al. published in Science reveals that structural disorder in nanoporous carbon materials significantly enhances their capacitance performance, suggesting that optimizing structural disorder is key to developing high‐energy‐density supercapacitors. This study innovatively shows that structural disorder in nanoporous carbon materials significantly enhances capacitance performance, surpassing traditional factors like pore size and surface area. The investigation of multiple nanoporous carbons from a range of different suppliers showcases the generalizability of the findings. Annealing treatment further confirms that the capacitance enhancement is due to structural disorder. This discovery guides the design and synthesis of new efficient electrode materials, providing a new direction for the future development of supercapacitors.

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Disorder Over Pore Size: Boosting Supercapacitor Efficiency

Zhang,

Wen

2024

Angew Chem Int Ed

1

0

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The urgent need for efficient energy storage systems has spotlighted supercapacitors and nanostructured porous carbon materials, which require structural optimization to enhance their performance and lifespan, necessitating advanced design and synthesis techniques. Recent research by Forse et al. published in Science reveals that structural disorder in nanoporous carbon materials significantly enhances their capacitance performance, suggesting that optimizing structural disorder is key to developing high‐energy‐density supercapacitors. This study innovatively shows that structural disorder in nanoporous carbon materials significantly enhances capacitance performance, surpassing traditional factors like pore size and surface area. The investigation of multiple nanoporous carbons from a range of different suppliers showcases the generalizability of the findings. Annealing treatment further confirms that the capacitance enhancement is due to structural disorder. This discovery guides the design and synthesis of new efficient electrode materials, providing a new direction for the future development of supercapacitors.

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Fenton Reaction Doubled Biomass Carbon Activation Efficiency for High‐Performance Supercapacitors

Cited by 24 publications

References 59 publications

Utilizing Manganese Phase Transition in Bioabsorption Synthesis of MnO@Carbon Composites for Enhanced High-Performance Supercapacitors

Utilizing Manganese Phase Transition in Bioabsorption Synthesis of MnO@Carbon Composites for Enhanced High-Performance Supercapacitors

Disorder Over Pore Size: Boosting Supercapacitor Efficiency

Disorder Over Pore Size: Boosting Supercapacitor Efficiency

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