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Deciphering energy storage mechanisms and pore structure effects in sugarcane bagasse-derived biomass carbon for lithium – ion batteries and supercapacitors

Q.N. Nguyen, Trọng Nghĩa Nguyễn, Thuy Trang T. Vuong, Viet‐Phuong La, Thi Viet Bac Phung, Nhat M. Nguyen, Phat Tan Vu, Van Hoang Nguyen, Mỹ Loan Phụng Lê, Phi Long Nguyen

2025Biomass and Bioenergy7 citationsDOIOpen Access PDF

Abstract

Biomass porous carbon material is a potential electrode candidate. However, it remains challenging to understand the energy storage mechanisms and the influence of pore architecture, which are evaluated holistically in this study. In detail, sugarcane bagasse carbon (SC) materials were synthesized and activated using sodium hydroxide, exhibiting surface areas exceeding 200 m 2 g −1 , making them highly suitable for use in batteries and supercapacitors. Among the tested anodes, SC700 demonstrated outstanding performance, delivering a specific capacity of 369.2 mAh.g −1 at 0.1 A g −1 and retaining 190.2 mAh.g −1 at 5 A g −1 . Even after 150 cycles at 0.5 A g −1 , SC700 maintained a retention rate of 80.03 %, which is attributed to ion mainly adsorption by the optimal balance of microporous and mesoporous structures. Additionally, SC800 excelled in high-rate cycling, attributed to its macro-porous structure and pseudo-capacitive behavior, which improve ion adsorption and facilitate efficient energy release, making it particularly suitable for powering high-energy devices. These findings provide deeper insights into the structure-property relationship of biomass-derived porous carbon, paving the way for sustainable energy solutions. • m 2 gIn this study, sugarcane bagasse-derived carbon (SC) was synthesized in Vietnam, activated with NaOH, and applied for electrodes for lithium-ion batteries and supercapacitors. • 1 A g A gA gThe SC materials exhibit impressive surface areas ranging from 200 to 300 m 2 .g -1 , making them highly suitable for diverse energy applications • Specifically, SC700 demonstrates high capacities at current densities of 1 and 2 A.g -1 , while maintaining excellent performance at 5 A.g -1 with a capacity of 190 mAh.g -1 . • In contrast, SC800 displays at high-rate densities, enabling rapid charge/discharge cycles due to its macroporous structure and large surface area. • These findings offer valuable insights into the structure–property relationships of biomass-derived porous carbon, advancing the development of sustainable energy solutions.

Topics & Concepts

BagasseSupercapacitorMaterials scienceEnergy storageCarbon fibersMicroporous materialAdsorptionActivated carbonChemical engineeringBiomass (ecology)Lithium (medication)Mesoporous materialPorosityNanotechnologySpecific surface areaBattery (electricity)IonElectrodeSpecific energyCurrent collectorSodiumLithium-ion batteryElectrolyteEnergy transformationNegative carbon dioxide emissionSupercapacitor Materials and FabricationAdvancements in Battery MaterialsAdvanced Battery Technologies Research