Capillary Evaporation on High-Dense Conductive Ramie Carbon for Assisting Highly Volumetric-Performance Supercapacitors

Conductive biomass carbon possesses unique properties of excellent conductivity and outstanding thermal stability, which can be widely used as conductive additive. However, building the high-dense conductive biomass carbon with highly graphitized microcrystals at a lower carbonization temperature is...

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Bibliographic Details
Published in:Small (Weinheim an der Bergstrasse, Germany) Germany), 2023-10, Vol.19 (42), p.e2303349-e2303349
Main Authors: Wang, Qing, Chen, Zhenyu, Luo, Qitian, Li, Haijian, Li, Jie, Yang, Weiqing
Format: Article
Language:English
Subjects:
Biomass
Carbon
Commercialization
Electrical resistivity
Evaporation
Graphitization
Leakage current
Microcrystals
Nanotechnology
Supercapacitors
Tap density
Thermal stability
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Summary:Conductive biomass carbon possesses unique properties of excellent conductivity and outstanding thermal stability, which can be widely used as conductive additive. However, building the high-dense conductive biomass carbon with highly graphitized microcrystals at a lower carbonization temperature is still a major challenge because of structural disorder and low crystallinity of source material. Herein, a simple capillary evaporation method to efficiently build the high-dense conductive ramie carbon (hd-CRC) with the higher tap density of 0.47 cm g than commercialized Super-C45 (0.16 cm g ) is reported. Such highly graphitized microcrystals of hd-CRC can achieve the high electrical conductivity of 94.55 S cm at the yield strength of 92.04 MPa , which is higher than commercialized Super-C45 (83.92 S cm at 92.04 MPa). As a demonstration, hd-CRC based symmetrical supercapacitors possess a highly volumetric energy density of 9.01 Wh L at 25.87 kW L , much more than those of commercialized Super-C45 (5.06 Wh L and 19.30 kW L ). Remarkably, the flexible package supercapacitor remarkably presents a low leakage current of 10.27 mA and low equivalent series resistance of 3.93 mΩ. Evidently, this work is a meaningful step toward high-dense conductive biomass carbon from traditional biomass graphite carbon, greatly promoting the highly-volumetric-performance supercapacitors.
ISSN:1613-6810
1613-6829
DOI:10.1002/smll.202303349