Litcius/Paper detail

Activation-Free Synthesis of Chitin-Derived Porous Carbon: Application for Electrical Energy Storage

Hiroyuki Itoi, Ginga Saeki, Takanori Usami, Sho Takagi, Hayato Suzuki, Takafumi Ishii, Hiroyuki Iwata, Yoshimi Ohzawa

2024ACS Sustainable Resource Management13 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide Chitin-derived porous carbons (CDPCs) are synthesized by simply carbonizing chitin at 850 °C for 1 h under a N 2 atmosphere. This method is very simple and does not require any activation or washing processes. We study the effects of the heating rate (2–20 °C min –1 ) on their structural characteristics and electric double-layer capacitor performance. Pore development proceeds above 300 °C during heating chitin, and nitrogen in chitin remains in the CDPCs with nitrogen/carbon molar ratios of 0.053–0.055. Although their specific surface areas are only 300–327 m 2 g –1, three-electrode cell measurements in 1 M H 2 SO 4 reveal that their gravimetric and area-normalized capacitances at 0.05 A g –1 are as high as 173–177 F g –1 and 54–57 μF cm –2, respectively. The area-normalized capacitances exceed those reported for activated carbons derived from chitin. Moreover, they show high capacitance retentions of 49–52% at 10 A g –1 . Their high area-normalized capacitances and capacitance retentions are attributed to the coexistence of ultramicropores and mesopores along with high electrical conductivity due to a large amount of quaternary nitrogen and the absence of activation. Symmetrical two-electrode cell measurements show the practical energy and power densities of 4.9 W h kg –1 at 11.3 W kg –1 and 1.1 W h kg –1 at 1.5 kW kg –1 with a long cycle lifetime of 10,000 cycles. Our study demonstrates the significant contribution of utilizing biomass for electrode materials, aligning with the objectives of both United Nation’s Sustainable Development Goals 7 and 12. By enhancing clean energy accessibility (SDG 7) and promoting responsible consumption and production practices (SDG 12) through efficient resource utilization, we have paved the way for a more sustainable energy future.

Topics & Concepts

ChitinEnergy storageMaterials scienceChemical engineeringPorosityCarbon fibersPorous mediumChemistryComposite materialChitosanEngineeringComposite numberPower (physics)PhysicsThermodynamicsSupercapacitor Materials and FabricationConducting polymers and applicationsAdvanced Battery Materials and Technologies
Activation-Free Synthesis of Chitin-Derived Porous Carbon: Application for Electrical Energy Storage | Litcius