高温热处理对三维多孔石墨烯电化学性能的影响

doi:10.12028/j.issn.2095-4239.2019.0147

储能科学与技术 ›› 2020, Vol. 9 ›› Issue (1): 65-69.doi: 10.12028/j.issn.2095-4239.2019.0147

高温热处理对三维多孔石墨烯电化学性能的影响

伍世嘉¹(), 肖祥¹, 王超¹(), 钟国彬¹, 李欣¹, 郑超², 阮殿波²

1. 广东电网有限责任公司电力科学研究院，广东广州 510080
2. 宁波中车新能源科技有限公司，浙江宁波 315112

收稿日期:2019-07-01 修回日期:2019-07-29 出版日期:2020-01-05 发布日期:2020-01-10
通讯作者: 王超 E-mail:13920132353@163.com;wangchaomly@163.com
作者简介:伍世嘉（1989—），男，博士，研究方向为电化学储能材料制备，E-mail：13920132353@163.com；
基金资助:
中国南方电网有限责任公司科技项目(GDKJXM20160000)

Effect of high temperature heat treatment on electrochemical properties of three-dimensional porous graphene

WU Shijia¹(), XIAO Xiang¹, WANG Chao¹(), ZHONG Guobin¹, LI Xin¹, ZHENG Chao², RUAN Dianbo²

1. Electric Power Research Institute of Guangdong Power Grid Co. , Ltd. , Guangzhou 510080, Guangdong, China
2. Ningbo CRRC New Energy Technology Co. , Ltd. , Ningbo 315112, Zhejiang, China

Received:2019-07-01 Revised:2019-07-29 Online:2020-01-05 Published:2020-01-10
Contact: Chao WANG E-mail:13920132353@163.com;wangchaomly@163.com

摘要/Abstract

摘要：

三维多孔石墨烯由于其独特的三维结构、高比表面积、优良的导电性能和多级孔径结构，被广泛用作超级电容器用电极材料。但目前三维多孔石墨烯的单位面积利用率仍然较低，其单位面积比容量仅有5.35 μF/cm²，远低于碳基材料的理论值(约21 μF/cm²)。为了提高三维多孔石墨烯的单位面积比容量，选择一种高比表面积的三维多孔石墨烯为研究对象，通过对其进行高温热处理，重点考察了高温热处理对三维多孔石墨烯材料导电性的影响，以及导电性能的变化对三维多孔石墨烯电化学性能的影响。研究发现高温热处理后三维石墨烯材料的比表面积由2009.8 m²/g急剧降低到1301.0 m²/g，这主要是由于高温热处理后活化石墨烯颗粒体积收缩，孔体积降低。拉曼光谱结果表明，高温热处理可以提高三维多孔石墨烯的石墨化程度，提高其导电性，EIS结果表明其等效串联内阻由处理前的4.0 Ω降低到1.4 Ω。导电性的提高使得单位面积比容量的保持率由原来的34.8%提高至45.2%，这表明三维多孔石墨烯的单位面积利用率得到明显提升。研究结果为三维多孔石墨烯电极材料的可控制备提供理论依据。

关键词: 三维多孔石墨烯, 超级电容器, 热处理, 电化学性能

Abstract:

Three-dimensional porous graphene (TDPG) is extensively used as an electrode material for supercapacitors because of its unique three-dimensional structure, high specific surface area, high conductivity, and multilevel pore diameters. However, the specific capacitance per unit area of TDPG is only approximately 5.35 μF/cm², which is considerably lower than the theoretical value of a carbon-based material (~21 μF/cm²). A TDPG with a high specific surface area was selected for this study to improve the specific capacitance per unit area. The effect of high-temperature heat treatment on the conductivity of TDPG was investigated along with the effect of the changes in conductivity on its electrochemical properties. The results denoted that the specific surface area of TDPG was drastically reduced from 2009.8 to 1301.0 m²/g after the high-temperature heat treatment, which was mainly due to the shrinkage of the graphene particles and the reduction of pore volume. The Raman spectrum results demonstrated that high-temperature heat treatment could improve the degree of graphitization of TDPG and increase the conductivity of the electrode materials. Electron impact spectroscopy verified that the equivalent series internal resistance of button supercapacitors with TDPG as the electrode was reduced from 4.0 Ω to 1.4 Ω after heat treatment. The increase in conductivity helped to increase the specific capacity retention rate from 34.8% to 45.2%, indicating that the specific capacitance per unit area of TDPG was considerably improved by high-temperature heat treatment. The study provides a theoretical basis for the controllable preparation of the TDPG electrode materials.

Key words: three-dimensional porous graphene, supercapacitor, high temperature heat treatment, electrochemical properties

中图分类号:

TQ 152

伍世嘉, 肖祥, 王超, 钟国彬, 李欣, 郑超, 阮殿波. 高温热处理对三维多孔石墨烯电化学性能的影响[J]. 储能科学与技术, 2020, 9(1): 65-69.

WU Shijia, XIAO Xiang, WANG Chao, ZHONG Guobin, LI Xin, ZHENG Chao, RUAN Dianbo. Effect of high temperature heat treatment on electrochemical properties of three-dimensional porous graphene[J]. Energy Storage Science and Technology, 2020, 9(1): 65-69.

图/表 5

参考文献 12

1	NOVOSELOV K S, GEIM A K, MOROZOV S V, et al. Electric field effect in atomically thin carbon films[J]. Science, 2004, 306(5696): 666-669.
2	王超, 苏伟, 钟国彬, 等. 超级电容器及其在新能源领域的应用[J]. 广东电力, 2015, 28(12): 46-52
	WANG C, SU W, ZHONG G B, et al. Super capacitor and its application in new energy field[J]. Guangdong Electric Power, 2015, 28(12): 46-52.
3	ZHU Y, MURALI S, STOLLER M D, et al. Carbon-based supercapacitors produced by activation of graphene[J]. Science, 2011, 332(6037): 1537-1541.
4	阮殿波. 石墨烯/活性炭复合电极材料超级电容器的制备研究[D]. 天津: 天津大学, 2014.
	RUAN D B. The preparation of the supercapacitor of the composite electrode material of graphene/activated carbon[D]. Tianjin: Tianjin University, 2014.
5	郑超, 周旭峰, 刘兆平, 等. 活性石墨烯/活性炭干法复合电极制备及其在超级电容器中的应用[J]. 储能科学与技术, 2016, 5(4): 486-491.
	ZHENG C, ZHOU X F, LIU Z P, et al. Preparation of activated graphene/activated carbon dry composite electrode and its application in supercapacitors[J]. Energy Storage Science and Technology, 2016, 5(4): 481-491.
6	LIU C, YU Z, NEFF D, et al. Graphene-based supercapacitor with an ultrahigh energy density[J]. Nano Letters, 2010, 10(12): 4863-4868.
7	WU Z S, PARVEZ K, FENG X, et al. Graphene-based in-plane micro-supercapacitors with high power and energy densities[J]. Nature Communications, 2013, 4: doi: 10.1038/ncomms3487.
8	WU N L, WANG S Y. Conductivity percolation in carbon-carbon supercapacitor electrodes[J]. J. Power Sources, 2002, 110(1): 233-236.
9	JUNG H J, KIM Y J, HAN J H, et al. Thermal-treatment-induced enhancement in effective surface area of single-walled carbon nanohorns for supercapacitor application[J]. J. Phys. Chem. C, 2013, 117(49): 25877-25883.
10	ZHENG C, ZHOU X F, CAO H L, et al. Controllable synthesis of activated graphene and its application in supercapacitors[J]. J. Mat. Chem. A, 2015, 3: 9543-9549.
11	GRAF D, MOLITOR F, ENSSLIN K, et al. Spatially resolved raman spectroscopy of single- and few-layer graphene[J]. Nano Lett., 2007, 7(2): 238-242.
12	FERRARI A C. Raman spectroscopy of graphene and graphite: Disorder, electron-phonon coupling, doping and nonadiabatic effects[J]. Solid State Commun., 2007, 143(1/2): 47-57.

[1]	王宇作, 卢颖莉, 邓苗, 杨斌, 于学文, 荆葛, 阮殿波. 超级电容器自放电的研究进展[J]. 储能科学与技术, 2022, 11(7): 2114-2125.
[2]	魏超超, 余创, 吴仲楷, 彭林峰, 程时杰, 谢佳. Li₃PS₄ 固态电解质的研究进展[J]. 储能科学与技术, 2022, 11(5): 1368-1382.
[3]	郭铁柱, 周迪, 张传芳. MXenes胶体氧化的调控策略及其对超级电容器性能的影响[J]. 储能科学与技术, 2022, 11(4): 1165-1174.
[4]	林楠, KREWER Ulrike, ZAUSCH Jochen, STEINER Konrad, 林海波, 冯守华. 电化学能量储存和转换体系多物理场模型的建立及其应用[J]. 储能科学与技术, 2022, 11(4): 1149-1164.
[5]	岳博文, 佟佳欢, 刘玉文, 霍锋. 离子液体电解液的模拟计算方法及应用[J]. 储能科学与技术, 2022, 11(3): 897-911.
[6]	佟永丽, 武祥. 金属有机框架衍生的Co₃O₄ 电极材料及其电化学性能[J]. 储能科学与技术, 2022, 11(3): 1035-1043.
[7]	韩雪, 邓伟, 周旭峰, 刘兆平. 石墨烯在储能领域应用的专利分析[J]. 储能科学与技术, 2022, 11(1): 335-349.
[8]	乔亮波, 张晓虎, 孙现众, 张熊, 马衍伟. 电池-超级电容器混合储能系统研究进展[J]. 储能科学与技术, 2022, 11(1): 98-106.
[9]	苏少鹏, 李进, 张佃平, 李严, 席文, 李杨. 红柳基锂电池负极材料的制备及电化学性能[J]. 储能科学与技术, 2021, 10(6): 2082-2089.
[10]	王凯, 侯朝霞, 李思瑶, 屈晨滢, 王悦, 孔佑健. 可拉伸全固态超级电容器的研究进展[J]. 储能科学与技术, 2021, 10(3): 887-895.
[11]	陈帅, 陈灵, 江浩. 氮掺杂无定形氧化钒纳米片阵列用于快充型准固态超级电容器[J]. 储能科学与技术, 2021, 10(3): 945-951.
[12]	刘当玲, 王诗敏, 高智慧, 徐露富, 夏书标, 郭洪. 三维NZSPO/PAN-［PEO-NaTFST］复合钠离子电池固体电解质[J]. 储能科学与技术, 2021, 10(3): 931-937.
[13]	朱鑫鑫, 蒋伟, 万正威, 赵澍, 李泽珩, 王利光, 倪文斌, 凌敏, 梁成都. 固态锂硫电池电解质及其界面问题研究进展[J]. 储能科学与技术, 2021, 10(3): 848-862.
[14]	毕志杰, 赵宁, 郭向欣. 基于氧化钨和普鲁士蓝的可变色超级电容器[J]. 储能科学与技术, 2021, 10(3): 952-957.
[15]	杨春燕, 马云龙, 冯小琼, 张世英, 安长胜, 李劲风. 碳基材料在铝离子电池中的研究进展[J]. 储能科学与技术, 2021, 10(2): 432-439.

高温热处理对三维多孔石墨烯电化学性能的影响

Effect of high temperature heat treatment on electrochemical properties of three-dimensional porous graphene

RichHTML

PDF

可视化

摘要/Abstract

引用本文

使用本文

图/表 5

参考文献 12

相关文章 15

编辑推荐

Metrics

本文评价