Graphical Abstract
Newswise — In a new review (https://doi.org/10.1016/j.recm.2023.12.002) published in the KeAi journal Resources Chemicals and Materials, a team of researchers from China examined the potential of biomass-derived carbon materials for high-performance rechargeable battery electrodes.
A key information that stood out was the authors' emphasis on the hydrothermal method as an approach for synthesizing biomass-derived carbon materials. "In our assessment, we posit that the hydrothermal method stands out as the most promising approach for crafting biomass-derived carbon materials. This technique not only offers a high degree of control but also demonstrates remarkable efficacy in tailoring the microstructure of these materials,” says Qiankun Zhou.
This underscores the importance of precise microstructure control in optimizing the performance of these carbon materials, and the hydrothermal method appears to offer a unique advantage in this regard.
Another interesting aspect of the review is a summary of incorporating other elements into the biomass carbon structures to achieve synergistic effects. The authors suggest that this strategic amalgamation can lead to superior performance in ion batteries.
"Achieving optimal performance often necessitates the incorporation of other elements into biomass carbon structures. This strategic amalgamation leads to a synergistic interaction between the various components, culminating in superior performance in ion batteries,” adds Zhou.
Throughout the review, the authors maintain a balanced perspective, acknowledging the challenges faced by biomass carbon materials, such as limited efficiency, modest yields, and complex fabrication processes. However, they firmly believe that these materials align with the trajectory of future development and possess extensive potential for applications beyond energy storage.
Overall, this review offers a comprehensive and insightful exploration of the use of biomass-derived carbon materials in high-performance rechargeable battery electrodes. It highlights the promising avenues for optimization through microstructure control and strategic incorporation of other elements, while recognizing the growing concerns surrounding the environmental impact of traditional metal-based electrode materials and the need for more sustainable alternatives.
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References
DOI
Original Source URL
https://doi.org/10.1016/j.recm.2023.12.002
Funding information
This work was co-financed by the University Synergy Innovation Program of Anhui Province (GXXT-2022-018), National Natural Science Foundation of China (22302052), Anhui Provincial Natural Science Foundation for Distinguished Young Scholar (2008085J26), Natural Science Foundation in University of Anhui Province (KJ2021ZD0119,2022AH040251 and 2023AH052190), Excellent Scientific Research and Innovation Team in University of Anhui Province (2022AH010096 and 2023AH010050), Startup Fund for Distinguished Scholars in Hefei University (20RC37) and Anhui Provincial Natural Science Foundation (2108085QB47).
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