abstract

• Abstract: In this work, it is proven that a biochar obtained from a commercial gasifier can be used as electrode material for supercapacitors (SC). This biochar was produced at 1000 °C from corn cob wastes (GAS), and was compared to an activated biochar obtained in a traditional lab pyrolysis process (LAB). Both biochars were characterized by different physicochemical techniques, observing their amorphous nature with well-developed microporosity dependent of their pretreatment and production methodology. Furthermore, a computational modeling based on Molecular Dynamics at the ReaxFF level was also performed to elucidate the geometry of the resulting microporous structure after simulated pyrolysis. X-ray structure and pore size distribution are in agreement with those results obtained via computational simulation. Both carbon materials were electrochemically evaluated in acidic electrolyte using 3 and 2 electrode systems, obtaining capacitances of 130 F g- 1 (20 mV s- 1), and excellent performance compared to commercial activated carbons, with only about 10%25 of capacitance loss after 5000 cycles. However, GAS performance in SC was higher than activated biochar due to its higher micropore volume. This study provides a novel useful application to use gasifier residues from agricultural biomass waste for energy storage devices. Graphic Abstract: [Figure not available: see fulltext.].s © 2020, Springer Nature B.V.

authors

• Betancourt-Mendiola M.D.L.
• Cuentas-Gallegos A.K.
• Guillén-López A.
• Martínez-Casillas D.C.
• Mascorro-Gutiérrez I.
• Muñiz J.
• Palestino Escobedo Alma Gabriela
• Pascoe-Sussoni J.E.
• Quiroga-González E.

publication date

• 2020-01-01

funding provided via

• Consejo Nacional de Ciencia y Tecnología, CONACYT: 279953, IA102820  Grant
• Fondo Sectorial Investigación para el Desarrollo Aeroportuario y la Navegación Aérea, ASA-CONACYT: A1-S-13294  Grant
• Universidad Nacional Autónoma de México, UNAM: LANCAD-UNAM-DGTIC-310, LANCAD-UNAM-DGTIC-370  Grant

published in

• Waste and Biomass Valorization  Journal

keywords

• Agricultural biomass waste; Biochar; Biomass gasification residue; Corncob waste; Molecular dynamics; Simulated pyrolysis; Supercapacitor Agricultural robots; Capacitance; Computational chemistry; Computational geometry; Electrodes; Electrolytes; Energy storage; Microporosity; Molecular dynamics; Pore size; Pyrolysis; Acidic electrolytes; Agricultural biomass; Commercial activated carbons; Computational model; Computational simulation; Electrode material; Micro-porous structure; Physicochemical techniques; Supercapacitor

Digital Object Identifier (DOI)

• 10.1007/s12649-020-01248-2

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