Synthesis of biochar and its metal oxide composites and application on next sustainable electrodes for energy storage devices

Next Materials Pub Date : 2024-12-03 DOI:10.1016/j.nxmate.2024.100444

Bruna Andressa Bregadiolli , Glauco Meireles Mascarenhas Morandi Lustosa , João Vitor Paulin , Waldir Antonio Bizzo , Lauro Tatsuo Kubota , Shuguang Deng , Talita Mazon

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Abstract

Biochar materials have been applied in energy storage due to their unique properties, such as high storage of ions, high conductivity, chemical stability and ease of production. Combining it with the high specific capacitance could be a promising strategy to develop devices and improve the properties. Through a hydrothermal technique the biochar powders were synthesized from sugarcane biomass. An acid pretreatment was carried out before and after the graphitization process aiming to obtain carbon materials with high surface area and porosity. The morphological characterization reveals powders with pores of submicrometer diameter. For the pure biochar it was determined a superficial area of 477.66 m².g⁻¹ with a median pore size of 42.92 Å and a pore volume of 0.21 cm³.g⁻¹. A carbon-based paste was then prepared to deposit on nickel foam and obtain the electrodes. In a 3-electrode system characterization, biochar has showed higher specific capacitance than the metal oxide composites due to higher surface area and higher medium pore diameter. It was calculated a resistance of 2.7 Ω, a capacitance of 446 mF.g⁻¹, a power density of 46.2 W.kg⁻¹ and an energy density of 1.8 W.h.kg⁻¹. These results indicate the potential use of biochar-based electrodes with high electrical conductivity and improved surface area to obtain higher capacitance properties for development of advanced devices.

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生物炭及其金属氧化物复合材料的合成及其在下一代可持续储能电极中的应用

生物炭材料由于具有离子储存量高、电导率高、化学稳定性好、易于生产等独特的性能，在储能领域得到了广泛的应用。将其与高比电容相结合可能是开发器件和改善性能的一种有前途的策略。以甘蔗为原料，采用水热法合成了生物炭粉体。在石墨化前后分别进行酸预处理，以获得具有高比表面积和高孔隙率的碳材料。形貌表征表明粉末具有亚微米孔径。纯生物炭的表面积为477.66 m2。G−1的中位孔径为42.92 Å，孔体积为0.21 cm3.g−1。然后制备碳基浆料沉积在泡沫镍上并获得电极。在三电极系统表征中，由于生物炭具有更高的比表面积和更高的介质孔径，因此比电容高于金属氧化物复合材料。经计算，其电阻为2.7 Ω，电容为446 mF。g−1，功率密度为46.2 W。能量密度为1.8 W.h.kg−1。这些结果表明，具有高导电性和改善表面积的生物炭基电极具有开发先进器件所需的更高电容性能的潜力。

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