上海大学学报(自然科学版) ›› 2021, Vol. 27 ›› Issue (2): 369-378.doi: 10.12066/j.issn.1007-2861.2157
陈恒桥, 吕丽萍, 吴明红(
)
收稿日期:2019-03-11
出版日期:2021-04-30
发布日期:2021-04-27
通讯作者:
吴明红
E-mail:mhwu@shu.edu.cn
作者简介:吴明红(1968—), 女, 教授, 博士生导师, 博士, 研究方向为能源纳米材料等. E-mail:mhwu@shu.edu.cn基金资助:
CHEN Hengqiao, LÜ Liping, WU Minghong()
Received:2019-03-11
Online:2021-04-30
Published:2021-04-27
Contact:
WU Minghong
E-mail:mhwu@shu.edu.cn
摘要:
介绍了一种通过简单的室温搅拌合成具有多孔结构的 Co-Mn 金属有机框架(metal-organic-framework, MOF)材料的方法, 并对制备的双金属 MOF 进行气相硫化, 得到多孔 CoS$_{2}$/MnS 双金属复合材料. 与相同方法制备的单金属 MnS 与 CoS$_{2}$ 材料对比 发现, CoS$_{2}$/MnS 双金属复合材料表现出了类似花瓣状的多孔片状结构以及更小的粒径, 在作为锂离子电池电极材料使用时表现出了最好的储锂性能. 这主要归因于类花瓣状的多孔结构: 一方面为锂离子提供了更短的传输路径以及更多的接触 位点; 另一方面也缓解了材料锂化/去锂化过程的体积变化. 此外, 两种金属硫化物的有机结合也抑制了材料在循环过程中由于体积变化而导致的容量快速衰减. 最后, MOF有机配体衍生的碳骨架也为增强材料的导电性起到了积极的作用.
中图分类号:
陈恒桥, 吕丽萍, 吴明红. Co-Mn 金属有机骨架衍生的双金属硫化物及其在锂离子电池负极材料中的应用[J]. 上海大学学报(自然科学版), 2021, 27(2): 369-378.
CHEN Hengqiao, LÜ Liping, WU Minghong. Design and application of Co-Mn metal-organic-frameworks derived bimetallic sulfides as anode for lithium-ion batteries[J]. Journal of Shanghai University(Natural Science Edition), 2021, 27(2): 369-378.
图1
CoS$_{2}$/MnS 和 CoS$_{2}$ 与 MnS 的 XRD 谱图"
图2
Co-Mn-BTC, Co-BTC 和 Mn-BTC 的 SEM 图"
图3
Co-Mn-BTC 的 TEM 图"
图4
CoS$_{2}$/MnS, CoS$_{2}$, MnS 的 SEM 图和 CoS$_{2}$/MnS 的 mapping 图像"
图5
CoS$_{2}$/MnS 的 TEM 图"
图6
CoS$_{2}$/MnS 的氮气等温吸附脱附曲线"
图7
CoS$_2$/MnS, MnS, CoS$_2$ 的恒电流充放电曲线图和 Nyquist 图"
图8
CoS$_2$/MnS, CoS$_2$ 和 MnS 的循环性能"
| [1] | Hu X, Li C, Lou X, et al. Hierarchical CuO octahedra inherited from copper metal-organic frameworks: high-rate and high-capacity lithium-ion storage materials stimulated by pseudocapacitance[J]. Journal of Materials Chemistry A, 2017,5(25):12828-12837. |
| [2] | Li C, Chen T Q, Xu W J, et al. Mesoporous nanostructured Co$_{3}$O$_{4}$ derived from MOF template: a high-performance anode material for lithium-ion batteries[J]. Journal of Materials Chemistry A, 2015,3(10):5585-5591. |
| [3] | Gao X, Wang B Y, Zhang Y, et al. Graphene-scroll-sheathed alpha-MnS coaxial nanocables embedded in N, S Co-doped graphene foam as 3D hierarchically ordered electrodes for enhanced lithium storage[J]. Energy Storage Materials, 2019,16:46-55. |
| [4] | Li B S, Wang R R, Chen Z L, et al. Embedding heterostructured MnS/Co$_{1-x}$S nanoparticles in porous carbon/graphene for superior lithium storage[J]. Journal of Materials Chemistry A, 2019,7(3):1260-1266. |
| [5] |
Wang R R, Li B S, Lai L F, et al. 3D urchin-like architectures assembled by MnS nanorods encapsulated in N-doped carbon tubes for superior lithium storage capability[J]. Chemical Engineering Journal, 2019,355:752-759.
doi: 10.1016/j.cej.2018.08.136 |
| [6] | Wang Y H, Zhang Y Y, Peng Y Y, et al. Physical confinement and chemical adsorption of porous C/CNT micro/nano-spheres for CoS and Co$_{9}$S$_{8}$ as advanced lithium batteries anodes[J]. Electrochimica Acta, 2019,299:489-499. |
| [7] | Lin W J, Huang Y H, He G Q. Unique CoS hierarchitectures for high-performance lithium ion batteries[J]. Crystengcomm, 2018,20(42):6727-6732. |
| [8] | Geng H B, Su H, Lin C H, et al. Double-layer N,S-codoped carbon protection of MnS nanoparticles enabling ultralong-life and high-rate lithium ion storage[J]. ACS Applied Energy Materials, 2018,1(9):4867-4873. |
| [9] | Yi X L, He W, Zhang X D, et al. Hollow mesoporous MnO/MnS/SiC/S-CN composites prepared from soda pulping black liquor for lithium-ion batteries[J]. Journal of Alloys and Compounds, 2018,735:1306-1313. |
| [10] | Lu J, Xia G, Gong S, et al. Metallic 1T phase MoS$_{2}$ nanosheets decorated hollow cobalt sulfide polyhedra for high-performance lithium storage[J]. Journal of Materials Chemistry A, 2018,6(26):12613-12622. |
| [11] |
Hong X, Kim J, Shi S F, et al. Ultrafast charge transfer in atomically thin MoS$_{2}$/WS$_{2}$ heterostructures[J]. Nat Nanotechnol, 2014,9(9):682-686.
doi: 10.1038/nnano.2014.167 pmid: 25150718 |
| [12] |
Kang W, Zhang Y, Fan L, et al. Metal-organic framework derived porous hollow Co$_{3}$O$_{4}$/N-C polyhedron composite with excellent energy storage capability[J]. ACS Appl Mater Interfaces, 2017,9(12):10602-10609.
pmid: 28287697 |
| [13] | Ji D, Zhou H, Tong Y L, et al. Facile fabrication of MOF-derived octahedral CuO wrapped 3D graphene network as binder-free anode for high performance lithium-ion batteries[J]. Chemical Engineering Journal, 2017,313:1623-1632. |
| [14] | Liu W, Yang H Z, Zhao L, et al. Mesoporous flower-like Co$_{3}$O$_{4}$/C nanosheet composites and their performance evaluation as anodes for lithium ion batteries[J]. Electrochimica Acta, 2016,207:293-300. |
| [15] | Han X, Chen W M, Han X G, et al. Nitrogen-rich MOF derived porous Co$_{3}$O$_{4}$/N-C composites with superior performance in lithium-ion batteries[J]. Journal of Materials Chemistry A, 2016,4(34):13040-13045. |
| [16] |
Li G R, Xie C C, Shen Z R, et al. Cobalt oxide 2D nano-assemblies from infinite coordination polymer precursors mediated by a multidentate pyridyl ligand[J]. Dalton Trans, 2016,45(18):7866-7874.
doi: 10.1039/c6dt00332j pmid: 27064264 |
| [17] | Zhang L M, Yan B, Zhang J H, et al. Design and self-assembly of metal-organic framework-derived porous Co$_{3}$O$_{4}$ hierarchical structures for lithium-ion batteries[J]. Ceramics International, 2016,42(4):5160-5170. |
| [18] | Xiu Z, Alfaruqi M H, Gim J, et al. Hierarchical porous anatase TiO$_{2}$ derived from a titanium metal-organic framework as a superior anode material for lithium ion batteries[J]. Chem Commun, 2015,51(61):12274-12277. |
| [19] | Zhang B W, Hao S J, Xiao D R, et al. Templated formation of porous Mn$_{2}$O$_{3}$ octahedra from Mn-MIL-100 for lithium-ion battery anode materials[J]. Materials & Design, 2016,98:319-323. |
| [20] |
Wang Q, Zou R, Xia W, et al. Facile Synjournal of ultrasmall CoS$_{2}$ nanoparticles within thin N-doped porous carbon shell for high performance lithium-ion batteries[J]. Small, 2015,11(21):2511-2517.
pmid: 25688868 |
| [21] |
Wu R, Wang D P, Rui X, et al. In-situ formation of hollow hybrids composed of cobalt sulfides embedded within porous carbon polyhedra/carbon nanotubes for high-performance lithium-ion batteries[J]. Adv Mater, 2015,27(19):3038-3044.
pmid: 25856242 |
| [22] |
Sun H, Xin G, Hu T, et al. High-rate lithiation-induced reactivation of mesoporous hollow spheres for long-lived lithium-ion batteries[J]. Nat Commun, 2014,5:4526.
pmid: 25077892 |
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