竹基超厚炭电极材料的制备及其电化学性能研究

doi:10.3969/j.issn.0253-2417.2022.02.002

摘要/Abstract

摘要：

以竹材为原料，通过直接炭化的方法保留竹材直孔结构制得超厚(2.5 mm)竹炭电极材料。在700、800和900℃炭化温度下分别制得竹炭材料Z-700、Z-800和Z-900，采用SEM、XPS、拉曼光谱等方法对竹炭材料进行表征。结果表明：竹材经过炭化处理后，仍保持原有孔道结构，其中炭化样品Z-900具有较高的BET比表面积(S_BET)可达483 m²/g，总孔容(V_total)为0.23 cm³/g，介孔孔容(V_mes)为0.05 cm³/g，微孔孔容(V_mic)为0.18 cm³/g。在6 mol/L KOH电解液中，电流密度为10 A/m²，所制备的超厚竹炭电极Z-900比电容高达22 F/cm²；当电流密度为200 A/m²时，比电容仍达到14.5 F/cm²，电容保持率为65.9%。以超厚竹炭电极Z-900组装成的对称超级电容器Z-900//Z-900，在电流密度为10 A/m²时，比电容为14 F/cm²，放电时间可达3 500 s，能量密度为4.9 W·h/m²，功率密度为5 W/m²。在100 A/m²电流密度下，10 000次循环后库仑效率可达99.8%，电容保持率为88%，表现出较高的电化学稳定性。

关键词: 生物质, 活性炭, 竹材, 超厚电极材料, 超级电容器

Abstract:

The 2.5 mm bamboo charcoal ultra-thick electrode material was prepared by direct carbonization of bamboo which preserved its straight pore structure. The bamboo charcoal materials Z-700, Z-800, and Z-900 were prepared at 700, 800 and 900 ℃, which were characterized by SEM, XPS, Raman spectra analysis. The results showed that the original bamboo structure was maintained after carbonization. Among them, the carbonized sample Z-900 owned a higher BET specific surface area(S_BET) of 483 m²/g, total pore volume(V_total) of 0.23 cm³/g, mesoporous pore volume(V_mes) of 0.05 cm³/g, and micropore volume(V_mic) of 0.18 cm³/g. Electrochemical performance tests showed that the specific capacitance of the prepared ultra-thick bamboo charcoal electrode Z-900 was as high as 22.0 F/cm² in the 6 mol/L KOH electrolyte with the current density of 10 A/m². When the current density was 200 A/m², the specific capacitance still reached 14.5 F/cm² and the capacitance retention rate was 65.9%. The symmetric supercapacitor Z-900//Z-900 assembled with ultra-thick bamboo charcoal electrode Z-900 owned a specific capacitance of 14 F/cm² at the current density of 10 A/m², which had a discharge time of 3 500 s, an energy density of 4.9 W·h/m², and a power density of 5 W/m². At the current density of 100 A/m², the coulomb efficiency could reach 99.8% after 10 000 cycles, and the capacitance retention was 88%, which demonstrated that Z-900 had an excellent electrochemical stability.

Key words: biomass, activated carbon, bamboo, ultra-thick electrode material, supercapacitor

中图分类号:

TQ35

于婷婷, 吕宗泽, 李想, 胡锦东, 李沛延, 李志国. 竹基超厚炭电极材料的制备及其电化学性能研究[J]. 林产化学与工业, 2022, 42(2): 10-18.

Tingting YU, Zongze LYU, Xiang LI, Jindong HU, Peiyan LI, Zhiguo LI. Preparation and Electrochemical Properties of Bamboo Based Ultra-thick Carbonaceous Electrode Materials[J]. Chemistry and Industry of Forest Products, 2022, 42(2): 10-18.

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样品 sample	炭化温度/℃ carbonization temp.	元素分析/% elementary analysis			不同形式氧的原子百分比/% content of oxygen species
样品 sample	炭化温度/℃ carbonization temp.	C	N	O	O-Ⅰ	O-Ⅱ	O-Ⅲ
Z-700	700	73.52	1.83	24.65	61.41	21.18	17.41
Z-800	800	86.20	1.67	12.13	45.93	31.35	22.72
Z-900	900	85.44	1.89	12.66	46.48	26.81	26.17

样品 sample	比表面积/ (m²·g^-1) S_BET	总孔容/ (cm³·g^-1) V_total	介孔孔容/ (cm³·g^-1) V_mes	微孔孔容/ (cm³·g^-1) V_mic
Z-700	306	0.180	0.070	0.110
Z-800	379	0.184	0.055	0.129
Z-900	483	0.230	0.050	0.180

材料 material	电流密度/(A·m^-2) current density	比电容/(F·cm^-2) specific capacitance	能量密度/(W·h·m^-2) energy density	电解液 electrolyte	厚度/mm thickness	参考文献 reference
杨木poplar	10	3.723	6.9	2 mol/L KOH	0.9	^[23]
杨木poplar	10	3.6	16.0	1 mol/L Na₂SO₄	0.8	^[24]
木材wood	10	2.98	3.0	1 mol/L H₂SO₄	2.4	^[25]
竹材bamboo	10	22	4.9	6 mol/L KOH	2.5	本实验 this experiment

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