板栗壳生物炭高性能对称性超级电容器电极材料的制备及性能

doi:10.16085/j.issn.1000-6613.2020-1994

化工进展 ›› 2021, Vol. 40 ›› Issue (8): 4381-4387.DOI: 10.16085/j.issn.1000-6613.2020-1994

板栗壳生物炭高性能对称性超级电容器电极材料的制备及性能

王芳平(), 马婧, 李小亚, 乔艳, 周凯玲

甘肃省生物电化学与环境分析重点实验室，省部共建生态环境相关高分子材料教育部重点实验室，西北师范大学化学化工学院，甘肃兰州 730070

收稿日期:2020-09-29 出版日期:2021-08-05 发布日期:2021-08-12
通讯作者: 王芳平
作者简介:王芳平（1973—），女，博士，副教授，研究方向为电化学相关能源材料。E-mail：wangfp@nwnu.edu.cn。
基金资助:
国家自然科学基金(21065010)

Preparation and properties of chestnut shell-based biochar electrode material for high-performance symmetrical supercapacitor

WANG Fangping(), MA Jing, LI Xiaoya, QIAO Yan, ZHOU Kailing

Key Laboratory of Bioelectrochemistry & Environmental Analysis of Gansu；Key Laboratory of Eco-Environment-Related Polymer Materials，Ministry of Education of China；College of Chemistry and Chemical Engineering，Northwest Normal University, Lanzhou 730070, Gansu, China

Received:2020-09-29 Online:2021-08-05 Published:2021-08-12
Contact: WANG Fangping

摘要/Abstract

摘要：

以板栗壳为碳源（CC），经700℃炭化（CC700）后采用ZnCl₂活化，成功制备了高性能的超级电容器电极材料（CC700-Zn）。对电极材料的形貌和性能进行测试，发现CC700-Zn具有3D孔道网络结构，比表面积达813.9m2/g，这种具有高比表面积的孔道结构为电子传输提供了通道。三电极体系中，1A/g时比电容可达506F/g，经过10000圈的循环之后其比电容仍能保持初始值的91%；二电极体系中，用CC700-Zn组装的对称性电容器在1A/g下的比电容为118F/g，CV的扫描速率可增大至220mV/s，电势窗宽0~6V。功率密度为900W/kg时，能量密度为53.1W·h/kg，当功率密度增加至27000W/kg时，能量密度仍可保持27W·h/kg。表明用板栗壳作为碳源制备对称性超级电容器电极材料是可行的。

关键词: 板栗壳, 超级电容器, 多孔碳, 生物质

Abstract:

High performance supercapacitor electrode material (CC 700-Zn) was successfully prepared by using chestnut shell as carbon source (CC) and ZnCl₂ activation after carbonization of CC at 700℃. The morphology and performance of CC700-Zn electrode materials were tested. It was found that CC700-Zn had a 3D channel network structure with a specific surface area of 813.9m2/g, and the network structure formed by mesopores and micropores provided a channel for electronic transmission. In a three-electrode system, CC700-Zn showed a high specific capacitance of 506F/g at a current density of 1A/g and outstanding cycling stability of 91% capacitance retention after 10000 cycles. In a two-electrode system, a symmetrical capacitor was assembled with CC700-Zn. The symmetric capacitor had a specific capacitance of 118F/g at 1A/g, the scan rate of CV can be increased to 220mV/s, and the potential window width was 0~1.6V. When the power density was 900W/kg, the energy density was 53.1W·h/kg. When the power density was increased to 27000W/kg, the energy density can still be maintained at 27W·h/kg. The above results indicated that it was feasible to prepare symmetrical supercapacitor electrode materials using chestnut shell as carbon source.

Key words: chestnut shell, supercapacitor, porous carbon, biomass

中图分类号:

TM53

王芳平, 马婧, 李小亚, 乔艳, 周凯玲. 板栗壳生物炭高性能对称性超级电容器电极材料的制备及性能[J]. 化工进展, 2021, 40(8): 4381-4387.

WANG Fangping, MA Jing, LI Xiaoya, QIAO Yan, ZHOU Kailing. Preparation and properties of chestnut shell-based biochar electrode material for high-performance symmetrical supercapacitor[J]. Chemical Industry and Engineering Progress, 2021, 40(8): 4381-4387.

图/表 7

图1 材料的制备流程

图2 CC700和CC700-Zn的SEM图

图3 活化前与活化后活性炭的XRD和Raman曲线

图4 CC700-Zn的N2吸附解吸曲线和CC700-Zn的孔径分布曲线（1?=10-10m）

图5 不同炭化温度下活性炭的CV曲线和EIS曲线

图6 CC700-Zn在不同扫描速度下的CV曲线、GCD曲线、电流密度-比电容和循环稳定性

图7 CC700-Zn//CC700-Zn在不同电压窗口下的CV、不同扫描速率下的CV曲线、不同电流密度下的GCD曲线、电流密度-比电容、功率密度-能量密度关系曲线及循环稳定性

参考文献 23

1	ZHANG Yongqi, XIA Xinhui, KANG Jing, et al.Hydrothermal synthesized porous Co(OH)₂ nanoflake film for supercapacitor application[J]. Chinese Science Bulletin, 2012, 57(32): 4215-4219.
2	JI Chenchen, MI Hongyu, YANG Shengchun, et al. Latest advances in supercapacitors: from new electrode materials to novel device designs[J]. Chemical Society Review, 2018, 64(1): 9-34.
3	SONG Yu, MENG Bo, CHEN Xuexian, et al. Fabrication and characterization analysis of flexible porous nitrogen-doped carbon-based supercapacitor electrodes[J].Chinese Science Bulletin, 2016, 61(12): 1314-1322.
4	PANDOLFO A G, HOLLENKAMP A F. Carbon properties and their role in supercapacitors[J].Journal of Power Sources, 2006, (1)157: 11-27.
5	DEMARCONNAY L, RAYMUNDO-PINERO E, BÉGUIN F. A symmetric carbon/carbon supercapacitor operating at 1.6V by using a neutral aqueous solution[J].Electrochemistry Communications, 2010, 12(10): 1275-1278.
6	POTPHODE Darshna, SHARMA Chandra Shekhar. Pseudocapacitance induced candle soot derived carbon for high energy density electrochemical supercapacitors: non-aqueous approach[J].Journal of Energy Storage, 2020, 27: 1-10.
7	LU C, HUANG Y H, WU Y J. Camellia pollen-derived carbon for supercapacitor electrode material[J].Journal of Power Sources, 2018, 394: 9-16.
8	TIAN Qiang, WANG XiaoXue, XU Xiaoyang, et al.A novel porous carbon material made from wild rice stem and its application in supercapacitors[J].Materials Chemistry and Physics, 2018, 213: 267-276.
9	XIA JinSong, ZHANG Na, CHONG Shaokun, et al. Three-dimensional porous graphene-like sheets synthesized from biocarbon via low-temperature graphitization for a supercapacitor[J]. Green Chemistry, 2018, 20(3): 694-700.
10	WANG Xiaodong, YUN Sining, FANG Wen, et al. Layer-stacking activated carbon derived from sunflower stalk as electrode materials for high-performance supercapacitors[J]. ACS Sustainable Chemistry & Engineering, 2018, 6(9): 11397-11407.
11	CHENG Lulu, GUO Peizhi, WANG Rongyue, et al. Electrocapacitive properties of supercapacitors based on hierarchical porous carbons from chestnut shell[J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2014, 446: 127-133.
12	JIANG Man, ZHANG Jingli, XING Lingbao, et al. KOH‐Activated porous carbons derived from chestnut shell with superior capacitive performance[J]. Chinese Journal of Chemistry, 2016, 34(11): 1093-1102.
13	ABIOVE Adekunle Moshood, Farid Nasir ANI. Recent development in the production of activated carbon electrodes from agricultural waste biomass for supercapacitors: a review[J]. Renewable and Sustainable Energy Reviews, 2015, 52: 1282-1293.
14	LIU Ruonan, WANG Yahui, WU Xiaoliang. Two-dimensional nitrogen and oxygen co-doping porous carbon nanosheets for high volumetric performance supercapacitors[J]. Microporous and Mesoporous Materials, 2020, 295: 1-7.
15	LI Yunyong, LI Zesheng, SHEN Peikang. Simultaneous formation of ultrahigh surface area and three-dimensional hierarchical porous graphene-like networks for fast and highly stable supercapacitors[J].Adv. Mater., 2013, 25(17): 2474-2480.
16	WAN Liu, LI Xiang, LI Na. Multi-heteroatom-doped hierarchical porous carbon derived from chestnut shell with superior performance in supercapacitors[J]. Journal of Alloys and Compounds, 2019, 790: 760-771.
17	XU Qun, YANG Hongxia. Fabrication of hierarchical nanohybrids with assistance of supercritical CO₂ for high-performance supercapacitor applications[J]. Chinese Science Bulletin, 2015, 60(26): 2573-2578.
18	WAN Liu, WEI Wei, XIE Mingjiang, et al. Nitrogen, sulfur co-doped hierarchically porous carbon from rape pollen as high-performance supercapacitor electrode[J]. Electrochimica Acta, 2019, 311: 72-82.
19	WANG Jiashuai, ZHANG Xiao, LI Zhe, et al. Recent progress of biomass-derived carbon materials for supercapacitors[J]. Journal of Power Sources, 2020, 451: 1-17.
20	WU Jing, XIA Mingwei, ZHANG Xiong, et al. Hierarchical porous carbon derived from wood tar using crab as the template: performance on supercapacitor[J]. Journal of Power Sources, 2020, 455: 1-9.
21	PENG Xu, LI Dianqi, PENG Jing, et al. Two-dimensional graphene/quasi-two-dimensional graphene analogues for flexible supercapacitor in all-solid-state[J].Chinese Science Bulletin, 2013, 58(28): 2886-2894.
22	GOMEZ-MARTN A, GUTIERREZ-PARDO A, Martinez-Fernandez J, et al.Binder-free supercapacitor electrodes: optimization of monolithic graphitized carbons by reflux acid treatment[J].Fuel Processing Technology, 2020, 199: 1-9.
23	FENG Haobin, HU Hang, DONG Hanwu, et al. Hierarchical structured carbon derived from bagasse wastes: a simple and efficient synthesis route and its improved electrochemical properties for high-performance supercapacitors[J]. Journal of Power Sources, 2016, 302: 164-173.

[1]	王帅晴, 杨思文, 李娜, 孙占英, 安浩然. 元素掺杂生物质炭材料在电化学储能中的研究进展[J]. 化工进展, 2023, 42(8): 4296-4306.
[2]	张耀杰, 张传祥, 孙悦, 曾会会, 贾建波, 蒋振东. 煤基石墨烯量子点在超级电容器中的应用[J]. 化工进展, 2023, 42(8): 4340-4350.
[3]	吴亚, 赵丹, 方荣苗, 李婧瑶, 常娜娜, 杜春保, 王文珍, 史俊. 用于复杂原油乳液的高效破乳剂开发及应用研究进展[J]. 化工进展, 2023, 42(8): 4398-4413.
[4]	郑梦启, 王成业, 汪炎, 王伟, 袁守军, 胡真虎, 何春华, 王杰, 梅红. 菌藻共生技术在工业废水零排放中的应用与展望[J]. 化工进展, 2023, 42(8): 4424-4431.
[5]	关红玲, 杨辉, 井红权, 刘玉琼, 谷守玉, 王好斌, 侯翠红. 木质素基控释材料及其在药物输送和肥料控释中的应用[J]. 化工进展, 2023, 42(7): 3695-3707.
[6]	朱薇, 齐鹏刚, 苏银海, 张书平, 熊源泉. 生物油分级多孔碳超级电容器电极材料的制备及性能[J]. 化工进展, 2023, 42(6): 3077-3086.
[7]	于丁一, 李圆圆, 王晨钰, 纪永升. pH响应性木质素水凝胶的制备及药物控释[J]. 化工进展, 2023, 42(6): 3138-3146.
[8]	吴锋振, 刘志炜, 谢文杰, 游雅婷, 赖柔琼, 陈燕丹, 林冠烽, 卢贝丽. 生物质基铁/氮共掺杂多孔炭的制备及其活化过一硫酸盐催化降解罗丹明B[J]. 化工进展, 2023, 42(6): 3292-3301.
[9]	王志伟, 郭帅华, 吴梦鸽, 陈颜, 赵俊廷, 李辉, 雷廷宙. 生物质与塑料催化共热解技术研究进展[J]. 化工进展, 2023, 42(5): 2655-2665.
[10]	陈飞, 刘成宝, 陈丰, 钱君超, 邱永斌, 孟宪荣, 陈志刚. g-C₃N₄基超级电容器用电极材料的研究进展[J]. 化工进展, 2023, 42(5): 2566-2576.
[11]	王雪, 徐期勇, 张超. 木质纤维素类生物质水热炭化机理及水热炭应用进展[J]. 化工进展, 2023, 42(5): 2536-2545.
[12]	蔡江涛, 候刘华, 兰雨金, 张晨陈, 刘国阳, 朱由余, 张建兰, 赵世永, 张亚婷. 沥青基多孔炭材料的制备及在超级电容器中的应用进展[J]. 化工进展, 2023, 42(4): 1895-1906.
[13]	刘静, 林琳, 张健, 赵峰. 生物质基炭材料孔径调控及电化学性能研究进展[J]. 化工进展, 2023, 42(4): 1907-1916.
[14]	万茂华, 张小红, 安兴业, 龙垠荧, 刘利琴, 管敏, 程正柏, 曹海兵, 刘洪斌. MXene在生物质基储能纳米材料领域中的应用研究进展[J]. 化工进展, 2023, 42(4): 1944-1960.
[15]	王钰琢, 李刚. 硫、氮共掺杂三维石墨烯的全固态超级电容器[J]. 化工进展, 2023, 42(4): 1974-1982.

板栗壳生物炭高性能对称性超级电容器电极材料的制备及性能

Preparation and properties of chestnut shell-based biochar electrode material for high-performance symmetrical supercapacitor

RichHTML

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

图/表 7

参考文献 23

相关文章 15

编辑推荐

Metrics

本文评价