水热-炭化法制备菱角壳基硬炭及其储锂性能

doi:10.19799/j.cnki.2095-4239.2019.0254

储能科学与技术 ›› 2020, Vol. 9 ›› Issue (3): 818-825.doi: 10.19799/j.cnki.2095-4239.2019.0254

水热-炭化法制备菱角壳基硬炭及其储锂性能

王超¹, 肖祥¹(), 钟国彬¹, 王佩², 刘力铭², 赵亚彬², 时志强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.天津市先进纤维与储能技术重点实验室，天津工业大学材料科学与工程学院，天津 300387

收稿日期:2019-11-07 修回日期:2019-11-14 出版日期:2020-05-05 发布日期:2020-05-11
通讯作者: 肖祥,时志强 E-mail:xiaoxiang@gddky.csg.cn;shizhiqiang@tjpu.edu.cn
作者简介:王超（1988—），男，博士，高级工程师，从事电化学储能技术研究，E-mail：wangchaomly@163.com；
基金资助:
中国南方电网有限责任公司科技项目(GDKJXM20160000);广东电网有限责任公司储能技术研究重点实验室基金

Water chestnut-based hard carbon prepared by hydrothermal-carbonization method as anode for lithium ion battery

WANG Chao¹, XIANG XIAO¹(), ZHONG Guobin¹, WANG Pei², LIU Liming², ZHAO Yabin², SHI Zhiqiang²()

^1.Electric Power Research Institute of Guangdong Power Grid Co. Ltd, Guangzhou 510080, Guangdong, China
^2.Tianjin Key Laboratory of Advanced Fibers and Energy Storage, School of Material Science and Engineering, Tiangong University, Tianjin 300387, China

Received:2019-11-07 Revised:2019-11-14 Online:2020-05-05 Published:2020-05-11
Contact: XIAO XIANG,Zhiqiang SHI E-mail:xiaoxiang@gddky.csg.cn;shizhiqiang@tjpu.edu.cn

摘要/Abstract

摘要：

生物质硬炭材料由于具有大层间距、可控的孔隙和缺陷结构，非常适合应用于动力锂离子电池（LIB）的负极材料。本文以生物质菱角壳为前驱体，通过水热除杂和高温炭化法制备出高纯度的菱角壳基硬炭负极材料（HT-x）。该方法更加安全环保，而且节省材料的制备时间。采用扫描电子显微镜（SEM）、X射线衍射仪（XRD）、拉曼光谱（Raman）、透射电子显微镜（TEM）等表征其形貌、微晶结构及微结构，并采用恒电流充放电、循环伏安技术研究了其电化学储锂性能。结果表明：水热除杂具有较好的效果，同时碳化温度对材料的微观结构和储锂性能影响较大。样品HT-1100具有大的层间距（d₀₀₂=0.39 nm）和适中的比表面积（76.82 m²/g），在0.1 C（1 C=250 mA/g）电流密度下，可逆放电比容量最高可达405.6 mA·h/g，首次库仑效率为57.32 %；并具有良好的倍率性能，在4C电流密度下比容量仍可以达到167.6 mA·h/g；在0.4 C电流密度下循环300圈后容量保持在382.5 mA·h/g，显示出非常优异的循环性能。菱角壳基生物质硬炭材料用于锂离子电池负极材料研究，为实现菱角壳生物质变“废”为宝，最终实现绿色和高效资源化利用提供了实验支持。

关键词: 菱角壳, 水热法, 硬炭, 锂离子电池, 负极

Abstract:

With their large layer spacing and controllable pore and defect structures, hard biomass carbon materials are suitable anode materials for lithium ion batteries (LIB). In this paper, impurities were removed from a water-chestnut shell precursor by hydrothermal treatment, which is safer and more environmentally friendly than pickling and saves material preparation time. The hard carbons derived from the water chestnut shells were prepared as the anode materials at different high temperatures (HT-x). The morphologies, microcrystalline structures, and microstructures of the specimens were characterized by scanning electron microscopy, X-ray diffraction analysis, Raman spectroscopy, and transmission electron microscopy. As clarified in the results, the impurities were substantially removed from the precursor. The carbonization temperature significantly affected the microstructure and lithium storage performance of the material. Sample HT-1100 exhibited a large layer spacing (d₀₀₂=0.39 nm) and a moderate specific surface area (76.82 m²/g). Under a current density of 0.1 C (1 C=250 mA/g), the reversible discharge specific capacity of this sample reached 405.6 mA·h/g. The rate performance was also high, with a specific capacity of 181.3 mA·h/g at 4 C. After 300 cycles at a current density of 0.4 C, the capacity remained at 382.5 mA·h/g, showing excellent cycle performance. By applying hard carbon derived from water chestnut shells as the anode material in LIB, we provide experimental support for converting a waste product into a valuable commodity, ultimately realizing green and efficient resource utilization.

Key words: water chestnut shell, hydrothermal method, hard carbon, lithium ion battery, anode

中图分类号:

TQ 152

王超, 肖祥, 钟国彬, 王佩, 刘力铭, 赵亚彬, 时志强. 水热-炭化法制备菱角壳基硬炭及其储锂性能[J]. 储能科学与技术, 2020, 9(3): 818-825.

WANG Chao, XIANG XIAO, ZHONG Guobin, WANG Pei, LIU Liming, ZHAO Yabin, SHI Zhiqiang. Water chestnut-based hard carbon prepared by hydrothermal-carbonization method as anode for lithium ion battery[J]. Energy Storage Science and Technology, 2020, 9(3): 818-825.

图/表 9

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参考文献 27

1	ZHENG T, XING W, DAHN J R. Carbons prepared from coals for anodes of lithium-ion cells[J]. Carbon, 1996, 34(12): 1501-1507.
2	徐凯琪, 苏伟, 钟国彬, 等. 高容量锂离子电池硅基负极材料的研究进展[J]. 广东电力, 2017, 30(8): 1-7.
	XU K Q, SU W, ZHONG G B, et al. Research progress of silicon-based anode materials for high-capacity lithium-ion batteries[J]. Guangdong Electric Power, 2017, 30(8): 1-7.
3	郭建. 锂离子电池负极材料的研究进展[J]. 炭素, 2018(3): 39-42.
	GUO J. Research progress of negative electrode materials for lithium ion batteries[J]. Carbon, 2018(3): 39-42.
4	KALYANI P, ANITHA A. Biomass carbon & its prospects in electrochemical energy systems[J]. Hydrogen Energy, 2013, 38(10): 4034-4045.
5	ZHANG L, LIU Z, CUI G, et al. Biomass-derived materials for electrochemical energy storages[J]. Progress in Polymer Science, 2015, 43: 136-164.
6	LUX S F, PLACKE T, ENGELHARDT C, et al. Enhanced electrochemical performance of graphite anodes for lithium-ion batteries by dry coating with hydrophobic fumed silica[J]. Journal of the Electrochemical Society, 2012, 159(11): A1849-A1855.
7	KELLER M, VAALMA C, BUCHHOLZ D, et al. Cover picture: Development and characterization of high-performance sodium-ion cells based on layered oxide and hard carbon[J]. ChemElectroChem, 2016, 3(7): 1124-1132.
8	CAMPBELL B, IONESCU R, FAVORS Z, et al. Bio-derived, binderless, hierarchically porous carbon anodes for Li-ion batteries[J]. Scientific Reports, 2015, 5: doi: 10.1038/srep14575.
9	WU L, BUCHHOLZ D, VAALMA C, et al. Apple-biowaste-derived hard carbon as a powerful anode material for Na-ion batteries[J]. Chemelectrochem, 2016, 3(2): 292-298.
10	YUN J H, JEONG S K, NAHM K S, et al. Pyrolytic carbon derived from coffee shells as anode materials for lithium batteries[J]. Journal of Physics & Chemistry of Solids, 2007, 68(2): 182-188.
11	RYU D J, OH R G, SEO Y D, et al. Recovery and electrochemical performance in lithium secondary batteries of biochar derived from rice straw[J]. Environmental Science & Pollution Research International, 2015, 22(14): 10405-10412.
12	ZHANG Y, ZHANG F, LI G D, et al. Microporous carbon derived from pinecone hull as anode material for lithium secondary batteries[J]. Materials Letters, 2007, 61(30): 5209-5212.
13	STEPHAN A M, RAMESH S, KUMAR T P, et al. Pyrolitic carbon from biomass precursors as anode materials for lithium batteries[J]. Materials Science & Engineering A, 2006, 430(1): 132-137.
14	BHARDWAJ S, JAYBHAYE S, SHARON M, et al. Carbon nanomaterial from tea leaves as an anode in lithium secondary batteries[J]. Asian Journal of Experiment Science, 2008, 22(2): 89-93.
15	FEY T K, LEE D C, LIN Y Y, et al. High-capacity disordered carbons derived from peanut shells as lithium-intercalating anode materials[J]. Synthetic Metals, 2003, 139(1): 71-80.
16	FEY T K, LIN Y Y, HUANG K P, et al. Green energy anode materials: Pyrolytic carbons derived from peanut shells for lithium ion batteries[J]. Advanced Materials Research, 2012, 415/416/417: 1572-1585.
17	HWANG Y J, JEONG S K, SHIN J S, et al. High capacity disordered carbons obtained from coconut shells as anode materials for lithium batteries[J]. Journal of Alloys and Compounds, 2008, 448(1/2): 141-147.
18	PELED E, ESHKENAZI V, ROSENBERG Y. Study of lithium insertion in hard carbon made from cotton wool[J]. Journal of Power Sources, 1998, 76(2): 153-158.
19	LI W, CHEN M, WANG C. Spherical hard carbon prepared from potato starch using as anode material for Li-ion batteries[J]. Material Letters, 2011, 65(23/24): 3368-3370.
20	ZHENG P, LIU T, ZHANG J Z, et al. Sweet potato-derived carbon nanoparticles as anode for lithium ion battery[J]. RSC Advances, 2015, 5 (51): 40737-40741.
21	WANG J, YAN L, REN Q, et al. Facile hydrothermal treatment route of reed straw-derived hard carbon for high performance sodium ion battery[J]. Electrochimica Acta, 2018, 291: 188-196.
22	ZHU Z, LIANG F, ZHOU Z, et al. Expanded biomass-derived hard carbon with ultra-stable performance in sodium-ion batteries[J]. Journal of Materials Chemistry A, 2017, 6(4): 1513-1522.
23	BAI Y, LIU Y, LI Y, et al. Mille-feuille shaped hard carbons derived from polyvinylpyrrolidone: Via environmentally friendly electrostatic spinning for sodium ion battery anodes[J]. RSC Advances, 2017, 7(9): 5519-5527.
24	LONG Q, CHEN W, XU H, et al. Synthesis of functionalized 3D hierarchical porous carbon for high-performance supercapacitor[J]. Energy & Environmental Science, 2013, 6(8): 2497-2504.
25	HAO Y, CHEN C, YANG X, et al. Studies on intrinsic phase-dependent electrochemical properties of MnS nanocrystals as anodes for lithium-ion batteries[J]. Journal of Power Sources, 2017, 338: 9-16.
26	LI X, GENG D, ZHANG Y， et al. Superior cycle stability of nitrogen-doped graphene nanosheets as anodes for lithium ion batteries[J]. Electrochemistry Communications, 2011, 13(8): 822-825.
27	QIE L, CHEN W M, WANG Z H, et al. Nitrogen-doped porous carbon nanofiber webs as anodes for lithium ion batteries with a superhigh capacity and rate capability[J]. Advanced Materials, 2012, 24(15): 2047-2050.

样品	d₀₀₂	L_a/nm	L_c/nm	N	I_G/I_D
HT-900	0.40	2.38	1.15	3.88	0.34
HT-1100	0.39	2.50	1.20	4.06	0.42
HT-1300	0.38	3.49	1.69	5.43	0.48
HT-1500	0.37	3.85	1.86	6.01	0.57

样品	O/C	C（质量分数）/%	O（质量分数）/%	N（质量分数）/%	H（质量分数）/%
HT-900	0.06	93.15	5.25	0.59	0.71
HT-1100	0.03	95.72	3.27	0.54	0.67
HT-1300	0.01	97.46	1.16	0.20	0.35
HT-1500	0	97.75	0.56	0	0.17

样品	循环次数	放电容量/mA·h·g^-1	充电容量 /mA·h·g^-1	不可逆容量 /mA·h·g^-1	库仑效率/%
HT-900	1st	734.7	388	346.7	52.81
	2nd	394.5	357.8	36.7	90.70
HT-1100	1st	707.6	405.6	302.0	57.32
	2nd	400.2	368.2	32.0	92.00
HT-1300	1st	398.8	237.3	161.5	59.50
	2nd	250.8	236.4	14.4	94.26
HT-1500	1st	314.3	210.1	104.2	66.85
	2nd	230.5	205.7	24.8	89.24

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水热-炭化法制备菱角壳基硬炭及其储锂性能

Water chestnut-based hard carbon prepared by hydrothermal-carbonization method as anode for lithium ion battery

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