磷酸-硫酸协同制备木屑基碳材料及其电化学性能研究
收稿日期: 2024-04-03
网络出版日期: 2024-05-30
基金资助
国家自然科学基金项目(22068009);国家自然科学基金项目(22262006);贵州省科技创新人才团队项目(2018-5607);贵州省教育厅科技基金资助项目(2017-7254);贵州省百人计划项目(20165655);黔科合支撑项目([2023]043)
Study on synergistic preparation of wood chip based carbon materials with phosphoric acid-sulfuric acid and their electrochemical properties
Received date: 2024-04-03
Online published: 2024-05-30
以生物质废弃物木屑为原料,采用磷酸法、磷酸-硫酸协同活化法制备用于超级电容器电极材料的碳材料。通过BET、FT-IR、XPS、XRD和Raman等手段对生物炭的微观结构、化学组成及石墨化程度进行表征分析。结果表明:最佳制备工艺条件为磷酸木屑质量比(浸渍比)为2.0∶1、升温速率为10 ℃/min、活化温度为550 ℃、活化时间为60 min时,磷酸法木屑基碳材料的比表面积为1 717 m2/g、总孔容为1.00 cm3/g、微孔孔容为0.83 m3/g、中孔孔容为0.17 m3/g;磷酸-硫酸协同活化法木屑基碳材料(MSC-4-98)的比表面积为1 951 m2/g、总孔容为1.66 cm3/g、微孔孔容为0.60 m3/g、中孔孔容为1.06 m3/g;XPS等测试结果表明碳材料具有较高的石墨化程度。电化学性能测试结果表明,MSC-4-98在电流密度为0.5 A/g时比电容为250.38 F/g,当电流密度进一步增加到2.0 A/g时比电容依旧达到204.56 F/g,仍保持为最高比电容的81.7%,具有较高的比电容和较好的电容保持率。磷酸法制备的木屑碳材料,尽管具有高比表面积、高微孔率,但中孔不发达不满足电极材料要求;磷酸-硫酸协同制备的木屑基碳材料,具有高比表面积且中微双孔孔容均衡,电化学性能较为优异,在超级电容器应用中有巨大潜力。
于盼盼 , 吴宗金 , 吴浪 , 杨毅 , 林倩 , 潘红艳 . 磷酸-硫酸协同制备木屑基碳材料及其电化学性能研究[J]. 无机盐工业, 2025 , 57(4) : 79 -88 . DOI: 10.19964/j.issn.1006-4990.2024-0191
Carbon materials for supercapacitor electrode materials were prepared using biomass waste wood chips as raw materials by phosphoric acid method and phosphoric acid-sulfuric acid synergistic activation method.Characterization and analysis of the microstructure,chemical composition,and degree of graphitization of biochar were carried out using techniques such as BET,FT-IR,XPS,XRD,and Raman.The results showed that the optimal preparation process conditions were impregnation ratio of 2.0∶1,heating rate of 10 ℃/min,activation temperature of 550 ℃,and activation time of 60 min.The specific surface area of phosphoric acid based wood chip carbon material was 1 717 m2/g,total pore volume was 1.00 cm3/g,microporous pore volume was 0.83 m3/g,and mesoporous pore volume was 0.17 m3/g.The specific surface area of wood chip based carbon material(MSC-4-98) using phosphoric acid-sulfuric acid synergistic activation method was 1 951 m2/g,with a total pore volume of 1.66 cm3/g,a microporous pore volume of 0.60 m3/g,and a mesoporous pore volume of 1.06 m3/g.The results of XPS tests indicated that carbon materials had a high degree of graphitization.According to electrochemical performance tests,the specific capacitance of MSC-4-98 was 250.38 F/g at a current density of 0.5 A/g.When the current density was further increased to 2.0 A/g,the specific capacitance still reached 204.56 F/g,remaining at 81.7% of the highest specific capacitance,with high specific capacitance and good capacitance retention.Although the wood chip carbon material prepared by the phosphoric acid method had a high specific surface area and high porosity,the underdeveloped mesopores did not meet the requirements of electrode materials.The wood chip based carbon materials prepared with phosphoric acid and sulfuric acid had high specific surface area,well-developed and balanced mesopores,and excellent electrochemical performance,which had great potential in the application of supercapacitors.
| [1] | GAO Dan, LUO Zhiling, LIU Changhong,et al.A survey of hybrid energy devices based on supercapacitors[J].Green Energy & Environment,2023,8(4):972-988. |
| [2] | SIMON P, GOGOTSI Y.Materials for electrochemical capacito- rs[J].Nature Materials,2008,7:845-854. |
| [3] | RAWAT S, WANG C T, LAY C H,et al.Sustainable biochar for advanced electrochemical/energy storage applications[J].Journal of Energy Storage,2023,63:107115. |
| [4] | 中国经济网.推进生物质能多元化开发[N].经济日报,2023-01-11(11). |
| [5] | RAJESHKUMAR L, RAMESH M, BHUVANESWARI V,et al.Carbon nano-materials(CNMs) derived from biomass for energy storage applications:A review[J].Carbon Letters,2023,33(3):661-690. |
| [6] | YANG Qiang, GUO Jing, ZHANG Sen,et al.Utilizing waste pomelo peel to develop activated-doped porous biomass carbon as electrode materials:Study of activation mechanism,evaluation of electrochemical properties and assembly of symmetric supercapacito-rs[J].Industrial Crops and Products,2024,209:118060. |
| [7] | HEIDARINEJAD Z, DEHGHANI M H, HEIDARI M,et al.Methods for preparation and activation of activated carbon:A review[J].Environmental Chemistry Letters,2020,18(2):393-415. |
| [8] | 李金晓.基于特色植物材料的层次多孔炭制备及其超级电容性能研究[D].济南:山东大学,2020. |
| LI Jinxiao.Preparation of hierarchical porous carbon based on characteristic plant materials and research on its supercapacitor performance[D].Jinan:Shandong University,2020. | |
| [9] | 郭奇,许伟,刘军利.磷酸法木质素基活性炭的制备及其电化学性能研究[J].林产化学与工业,2022,42(2):31-38. |
| GUO Qi, XU Wei, LIU Junli.Preparation and electrochemical performance of lignin-based activated carbon by phosphoric acid activation[J].Chemistry and Industry of Forest Products,2022,42(2):31-38. | |
| [10] | 耿克奇,曹斌,宋怀河,等.磷酸活化制备棉杆基活性炭及其超级电容器性能研究[J].炭素技术,2017,36(1):53-57. |
| GENG Keqi, CAO Bin, SONG Huaihe,et al.Preparation and supercapacitor performance of activated carbons from cotton stalks with phosphoric acid as activators[J].Carbon Techniques,2017,36(1):53-57. | |
| [11] | PANT B, OJHA G P, ACHARYA J,et al.Eggshell membrane templated synthesis of Ni/MoC decorated carbon fibers with good electrochemical behavior[J].International Journal of Hydrogen Energy,2021,46(2):2774-2782. |
| [12] | 国家林业局. 双电层电容器专用活性炭[S].北京:中国标准出版社,2004. |
| [13] | 朱光真,邓先伦,刘晓敏.催化活化法制备高丁烷工作容量颗粒活性炭[J].功能材料,2011,42(S5):884-887,891. |
| ZHU Guangzhen, DENG Xianlun, LIU Xiaomin.Preparation of high butane working capacity granular activated carbon by catalytic activation method[J].Journal of Functional Materials,2011,42(S5):884-887,891. | |
| [14] | 王皓宇.制备生物质活性炭的“H3PO4-X”复合活化剂开发[D].重庆:重庆工商大学,2022. |
| WANG Haoyu.Development of "H3 PO4-X" composite activator for preparing biomass activated carbon[D].Chongqing:Chongqing Technology and Business University,2022. | |
| [15] | 左宋林.磷酸活化法制备活性炭综述(Ⅰ):磷酸的作用机理[J].林产化学与工业,2017,37(3):1-9. |
| ZUO Songlin.Review on phosphoric acid activation for preparation of activated carbon(Ⅰ):Roles of phosphoric acid[J].Chemistry and Industry of Forest Products,2017,37(3):1-9. | |
| [16] | ZHANG Zongbo, LEI Yuqi, LI Dawei,et al.Sudden heating of H3PO4-loaded coconut shell in CO2 flow to produce super activated carbon and its application for benzene adsorption[J].Renewable Energy,2020,153:1091-1099. |
| [17] | ZHANG Zongbo, LIU Xiaoyang, LI Dawei,et al.Effects of the ultrasound-assisted H3PO4 impregnation of sawdust on the properties of activated carbons produced from it[J].New Carbon Materials,2018,33(5):409-416. |
| [18] | LIU Hai, ZHANG Jian, BAO Nan,et al.Textural properties and surface chemistry of lotus stalk-derived activated carbons prepared using different phosphorus oxyacids:Adsorption of trimethoprim[J].Journal of Hazardous Materials,2012,235:367- 375. |
| [19] | GAO Yuan, YUE Qinyan, GAO Baoyu,et al.Insight into activated carbon from different kinds of chemical activating agents:A review[J].Science of the Total Environment,2020,746:141094. |
| [20] | NAHIL M A, WILLIAMS P T.Pore characteristics of activated carbons from the phosphoric acid chemical activation of cotton stalks[J].Biomass and Bioenergy,2012,37:142-149. |
| [21] | JIBRIL B, HOUACHE O, AL-MAAMARI R,et al.Effects of H3PO4 and KOH in carbonization of lignocellulosic material[J].Journal of Analytical and Applied Pyrolysis,2008,83(2):151- 156. |
| [22] | WANG Yahui, LIU Ruonan, TIAN Yadong,et al.Heteroatoms-doped hierarchical porous carbon derived from chitin for flexible all-solid-state symmetric supercapacitors[J].Chemical Engineering Journal,2020,384:123263. |
| [23] | 国家市场监督管理总局,中国国家标准化管理委员会. 超级电容器用活性炭[S].北京:中国标准出版社,2019. |
| [24] | BISWAL M, BANERJEE A, DEO M,et al.From dead leaves to high energy density supercapacitors[J].Energy & Environmental Science,2013,6(4):1249-1259. |
| [25] | QIN Qiqi, WANG Jingzheng, TANG Zhaoyu,et al.Mesoporous activated carbon for supercapacitors derived from coconut fiber by combining H3PO4-assisted hydrothermal pretreatment with KOH activation[J].Industrial Crops and Products,2024,208:117878. |
| [26] | SCHMID J, GROB B, NIESSNER R,et al.Multiwavelength Raman microspectroscopy for rapid prediction of soot oxidation reactivity[J].Analytical Chemistry,2011,83(4):1173-1179. |
| [27] | YAO Yushuai, GE Dan, YU Yi,et al.Filling macro/mesoporosity of commercial activated carbon enables superior volumetric supercapacitor performances[J].Microporous and Mesoporous Materials,2023,350:112446. |
| [28] | GONZáLEZ-DOMíNGUEZ J M, FERNáNDEZ-GONZáLEZ C, ALEXANDRE-FRANCO M,et al.Surface chemistry of cherry stone-derived activated carbon prepared by H3PO4 activation[J].Processes,2024,12(1):149. |
| [29] | ZHANG Renjie, ZHANG Wei, SHI Meiping,et al.Morphology controllable synthesis of heteroatoms-doped carbon materials for high-performance flexible supercapacitor[J].Dyes and Pigments,2022,199:109968. |
| [30] | NIE Weidong, LIU Yuanyuan, LI Jing,et al.A new carbon modification strategy aimed to fully address the issues of NiO as an electrode material for supercapacitors[J].Journal of Alloys and Compounds,2024,984:174027. |
| [31] | SU Hongyu, LAN Caining, WANG Zhouping,et al.Controllable preparation of eucommia wood-derived mesoporous activated carbon as electrode materials for supercapacitors[J].Polymers,2023, 15(3):663. |
| [32] | COSTENTIN C, PORTER T R, SAVéANT J M.How do pseudocapacitors store energy?Theoretical analysis and experimental illustration[J].ACS Applied Materials & Interfaces,2017,9(10):8649-8658. |
| [33] | 王永芳.含磷、氮活性炭的电化学应用基础研究[D].南京:南京林业大学,2018. |
| WANG Yongfang.Basic research on electrochemical application of activated carbon containing phosphorus and nitrogen[D].Nanjing:Nanjing Forestry University,2018. | |
| [34] | THUBSUANG U, CHOTIRUT S, THONGNOK A,et al.Facile preparation of polybenzoxazine-based carbon microspheres with nitrogen functionalities:Effects of mixed solvents on pore structure and supercapacitive performance[J].Frontiers of Chemical Science and Engineering,2020,14(6):1072-1086. |
/
| 〈 |
|
〉 |
