St?ber法制备煤焦油酚基碳纳米球

• 1:太原理工大学省部共建煤基能源清洁高效利用国家重点实验室

• 2:太原理工大学煤科学与技术教育部重点实验室

• 3:太原理工大学材料科学与工程学院

• 4:山西省丹源碳素股份有限公司

Stober法制备煤焦油酚基碳纳米球.pdf

摘要(Abstract)：

煤焦油的直接排放和粗放利用会造成严重的环境污染，煤焦油利用的关键是绿色高价值.以中低温煤焦油中提取得到的小分子量酚类物质为碳源，利用St9ber法合成碳纳米球.考察了煤焦油提取酚添加量、预聚合温度、水热温度和水热时间对碳纳米球形貌的影响，研究发现当煤焦油提取酚添加量为50%(质量分数)、预聚合温度为60℃、水热温度为160℃和水热时长为24 h时，可以制备得到形貌规整、粒径均一的单分散碳纳米球.在该条件制备的碳纳米球(CTCNS)平均粒径667 nm,比表面积可达596 m²·g2·g^(-1),氮含量为2.42%(原子分数),作为潜在的超级电容器电极材料，在6 mol·L(-1),氮含量为2.42%(原子分数),作为潜在的超级电容器电极材料，在6 mol·L^(-1)KOH中，具有较好的电化学性能，比电容为123 F·g(-1) KOH中，具有较好的电化学性能，比电容为123 F·g^(-1).为煤焦油的绿色高值化利用提供了新的思路和实验依据.
The direct discharge and crude utilization of coal tar will cause serious environmental pollution, and green and high-value utilization is the key to coal tar utilization. In this paper, small molecular weight phenolics were extracted from low-medium temperature coal tar and used as carbon source to synthesize carbon nanospheres by St9ber method. The effects of the addition of coal tar-extracted phenols, pre-polymerization temperature, hydrothermal temperature and hydrothermal time on the morphology of carbon nanospheres were investigated. It was found that monodisperse carbon nanospheres with regular morphology and uniform particle size could be prepared when the doping amount of coal tar-extracted phenols was 50%(mass fraction), the pre-polymerization temperature was 60 ℃, the hydrothermal temperature was 160 ℃, and the hydrothermal time was 24 h. The prepared carbon nanospheres(CTCNS) under these conditions have an average particle size of 667 nm, a specific surface area of up to 596 m(-1).为煤焦油的绿色高值化利用提供了新的思路和实验依据.
The direct discharge and crude utilization of coal tar will cause serious environmental pollution, and green and high-value utilization is the key to coal tar utilization. In this paper, small molecular weight phenolics were extracted from low-medium temperature coal tar and used as carbon source to synthesize carbon nanospheres by St9ber method. The effects of the addition of coal tar-extracted phenols, pre-polymerization temperature, hydrothermal temperature and hydrothermal time on the morphology of carbon nanospheres were investigated. It was found that monodisperse carbon nanospheres with regular morphology and uniform particle size could be prepared when the doping amount of coal tar-extracted phenols was 50%(mass fraction), the pre-polymerization temperature was 60 ℃, the hydrothermal temperature was 160 ℃, and the hydrothermal time was 24 h. The prepared carbon nanospheres(CTCNS) under these conditions have an average particle size of 667 nm, a specific surface area of up to 596 m²·g2·g^(-1)and a nitrogen content of 2.42%(atomic fraction). The prepared carbon nanospheres were used as potential supercapacitor electrode materials with good electrochemical properties in 6 mol·L(-1) and a nitrogen content of 2.42%(atomic fraction). The prepared carbon nanospheres were used as potential supercapacitor electrode materials with good electrochemical properties in 6 mol·L^(-1)KOH, with a specific capacitance of 123 F·g(-1) KOH, with a specific capacitance of 123 F·g^(-1). This paper provides a new idea and experimental basis for the green and high-value utilization of coal tar.

关键词(KeyWords)：煤焦油;碳纳米球;St9ber法;超级电容器
coal tar;carbon nanospheres;St9ber method;supercapacitors

基金项目(Foundation):国家能源集团2030重大项目先导项目(GJNY2030XDXM-19-17);; 晋中市科技重点研发计划(Y201002)

作者(Authors):侯豪杰;黄瑞;杨莹;刘冬;冯宇;王建成;
Hou Haojie;Huang Rui;Yang Ying;Liu Dong;Feng Yu;Wang Jiancheng;State Key Laboratory of Clean and Efficient Coal Utilization,Taiyuan University of Technology;Key Laboratory of Coal Science and Technology,Ministry of Education,Taiyuan University of Technology;College of Materials Science and Engineering,Taiyuan University of Technology;Shanxi Danyuan Carbon Holdings Co.,Ltd.;

DOI:10.16366/j.cnki.1000-2367.2023.04.007

参考文献(References)：

• [1] HUANG R,YUAN X Z,YAN L J,et al.Carbon precursors in coal tar:extraction and preparation of carbon materials[J].Science of the Total Environment,2021,788:147697.

• [2] 冯新娟，闵小建，郑化安，等.中低温煤焦油重油正庚烷萃余物的反应(甲醛)分离与分析[J].燃料化学学报，2018,46(1):15-26.FENG X J,MIN X J,ZHENG H A,et al.Reaction(formaldehyde)separation and analysis of n-heptane extraction residue from heavy oil of medium and low temperature coal tar[J].Journal of Fuel Chemistry and Technology,2018,46(1):15-26.

• [3] NIU Z S,WANG Y G,SHEN J,et al.Insight into aromatic structures of a middle-temperature coal tar pitch by direct characterization and ruthenium ion-catalyzed oxidation[J].Fuel,2019,241:1164-1171.

• [4] 马明明，苏小平，闵小建，等.中低温煤焦油蒸馏过程中金属元素的迁移规律[J].化工进展，2018,37(9):3355-3361.MA M M,SU X P,MIN X J,et al.Migration law of metal elements during distillation of low temperature coal tar[J].Chemical Industry and Engineering Progress,2018,37(9):3355-3361.

• [5] 郑金欣，田育成，郝博天，等.中低温煤焦油基炭微球的制备[J].化工进展，2020,39(2):649-657.ZHENG J X,TIAN Y C,HAO B T,et al.Preparation of medium and low temperature coal tar-based mesocarbon microbeads[J].Chemical Industry and Engineering Progress,2020,39(2):649-657.

• [6] CASTRO-MU?IZ A,LORENZO-FIERRO S,MARTíNEZ-ALONSO A,et al.Ordered mesoporous carbons obtained from low-value coal tar products for electrochemical energy storage and water remediation[J].Fuel Processing Technology,2019,196:106152.

• [7] DU J,ZONG S,ZHANG Y,et al.Co-assembly strategy for uniform and tunable hollow carbon spheres with supercapacitor application[J].Journal of Colloid and Interface Science,2020,565:245-253.

• [8] LI Y,WANG J,FAN S S,et al.Nitrogen-doped hierarchically porous carbon spheres for low concentration CO2 capture[J].Journal of Energy Chemistry,2021,53:168-174.

• [9] BANG J H.Hollow graphitic carbon spheres for Pt electrocatalyst support in direct methanol fuel cell[J].Electrochimica Acta,2011,56(24):8674-8679.

• [10] ZHANG C G,LI J J,LIU E Z,et al.Synthesis of hollow carbon nano-onions and their use for electrochemical hydrogen storage[J].Carbon,2012,50(10):3513-3521.

• [11] ZHAO J N,WANG F L,ZHANG X,et al.Vibration damping of carbon nanotube assembly materials[J].Advanced Engineering Materials,2018,20(3):1700647.

• [12] LIU T,ZHANG L Y,YOU W,et al.Core-shell nitrogen-doped carbon hollow spheres/Co3O4 nanosheets as advanced electrode for high-performance supercapacitor[J].Small,2018,14(12):1702407.

• [13] LIU J,QIAO S Z,LIU H,et al.Extension of the St?ber method to the preparation of monodisperse resorcinol-formaldehyde resin polymer and carbon spheres[J].Angewandte Chemie(International Ed in English),2011,50(26):5947-5951.

• [14] MAO H Y,CHEN X W,HUANG R Z,et al.Fast preparation of carbon spheres from enzymatic hydrolysis lignin:effects of hydrothermal carbonization conditions[J].Scientific Reports,2018,8:9501.

• [15] MAO D J,DING S S,MENG L J,et al.One-pot microemulsion-mediated synthesis of Bi-rich Bi4O5Br2 with controllable morphologies and excellent visible-light photocatalytic removal of pollutants[J].Applied Catalysis B:Environmental,2017,207:153-165.

• [16] ZHAO H Y,ZHANG F,ZHANG S M,et al.Scalable synthesis of sub-100 nm hollow carbon nanospheres for energy storage applications[J].Nano Research,2018,11(4):1822-1833.

• [17] TIAN H,LIU J,O'DONNELL K,et al.Revisiting the St?ber method:design of nitrogen-doped porous carbon spheres from molecular precursors of different chemical structures[J].Journal of Colloid and Interface Science,2016,476:55-61.

• [18] CHEN J C,XUE Z T,FENG S S,et al.Synthesis of mesoporous silica hollow nanospheres with multiple gold cores and catalytic activity[J].Journal of Colloid and Interface Science,2014,429:62-67.

• [19] CHEN M F,YU D,ZHENG X Z,et al.Biomass based N-doped hierarchical porous carbon nanosheets for all-solid-state supercapacitors[J].Journal of Energy Storage,2019,21:105-112.

• [20] WANG X Y,WANG S F,SHEN K X,et al.Phosphorus-doped porous hollow carbon nanorods for high-performance sodium-based dual-ion batteries[J].Journal of Materials Chemistry A,2020,8(7):4007-4016.

• [21] SHAN D D,YANG J,LIU W,et al.Biomass-derived three-dimensional honeycomb-like hierarchical structured carbon for ultrahigh energy density asymmetric supercapacitors[J].Journal of Materials Chemistry A,2016,4(35):13589-13602.

• [22] WANG P,ZHANG G,LI M Y,et al.Porous carbon for high-energy density symmetrical supercapacitor and lithium-ion hybrid electrochemical capacitors[J].Chemical Engineering Journal,2019,375:122020.

• [23] ZHANG R,JING X X,CHU Y T,et al.Nitrogen/oxygen co-doped monolithic carbon electrodes derived from melamine foam for high-performance supercapacitors[J].Journal of Materials Chemistry A,2018,6(36):17730-17739.

• [24] SU Y H,JIANG H L,ZHU Y H,et al.Enriched graphitic N-doped carbon-supported Fe3O4 nanoparticles as efficient electrocatalysts for oxygen reduction reaction[J].Journal of Materials Chemistry A,2014,2(20):7281-7287.

• [25] 汤宏伟，秦亚雷，侯燕，等.沉淀法制备Na0.7MnO2.05及其水基超级电容器性能测试[J].betway官方app 学报(自然科学版),2017,45(3):102-105.TANG H W,QIN Y L,HOU Y,et al.Na0.7MnO2.05 via chemical precipitation synthesis as an electrode material for aqueous Na-ion supercapacitors[J].Journal of Henan Normal University(Natural Science Edition),2017,45(3):102-105.

• [26] RAN F T,YANG X B,XU X Q,et al.Green activation of sustainable resources to synthesize nitrogen-doped oxygen-riched porous carbon nanosheets towards high-performance supercapacitor[J].Chemical Engineering Journal,2021,412:128673.

• [27] GOMEZ-MARTIN A,MARTINEZ-FERNANDEZ J,RUTTERT M,et al.An electrochemical evaluation of nitrogen-doped carbons as anodes for lithium ion batteries[J].Carbon,2020,164:261-271.