负极材料是目前制约水系锂离子电池的关键因素。钒酸盐材料因为较高的比容量和合适的脱嵌锂电位被广泛用于水系锂离子电池的负极。结合研究结果,对钒酸盐材料在水系锂离子电池领域的研究现状进行了综述,重点对相关材料的晶体结构、电化学性能和容量衰减机制进行了分析,提出了进一步改善水系锂离子电池电化学性能的措施。
Anode materials have become the key factor restricting the development of aqueous lithium-ion battery (ALIB).Due to their high specific capacities and suitable lithium insertion/extraction potentials,vanadate ma-terials have been widely utilized as anode materials for ALIB.This paper reviewed the current research progress of ALIB on the basis of research results in our group and the emphasis was placed on their crystal structure, charge-discharge mechanism, synthesis methods and electrochemical properties. Meanwhile, improvement measures were put forward to further better the electrochemical properties of vanadate materials in ALIB.
参考文献
| [1] | G. J. Wang;Q. T. Qu;B. Wang;Y. Shi;S. Tian;Y. P. Wu;R. Holze .Electrochemical behavior of LiCoO{sub}2 in a saturated aqueous Li{sub}2SO{sub}4 solution[J].Electrochimica Acta,2009(4):1199-1203. |
| [2] | Wang YG;Lou JY;Wu W;Wang CX;Xia YY .Hybrid aqueous energy storage cells using activated carbon and lithium-ion intercalated compounds - III. Capacity fading mechanism of LiCo1/3Ni1/3Mn1/3O2 at different pH electrolyte solutions[J].Journal of the Electrochemical Society,2007(3):A228-A234. |
| [3] | 郑隽,贾鑫,王翀,郑明森,董全峰.锂离子电池正极材料LiNi1/3Co1/3Mn1/3O2在LiNO3溶液中的电化学性能研究[J].电化学,2010(02):151-155. |
| [4] | K.S.Abou-El-Sherbini;M.H.Askar .Lithium insertion into manganese dioxide polymorphs in aqueous electrolytes[J].Journal of solid state electrochemistry,2003(7):435-441. |
| [5] | Jayalakshmi M.;Rao MM.;Scholz F. .Electrochemical behavior of solid lithium manganate (LiMn2O4) in aqueous neutral electrolyte solutions[J].Langmuir: The ACS Journal of Surfaces and Colloids,2003(20):8403-8408. |
| [6] | Mi CH;Zhang XG;Li HL .Electrochemical behaviors of solid LiFePO4 and Li0.99Nb0.01FePO4 in Li2SO4 aqueous electrolyte[J].Journal of Electroanalytical Chemistry: An International Journal Devoted to All Aspects of Electrode Kinetics, Interfacial Structure, Properties of Electrolytes, Colloid and Biological Electrochemistry,2007(2):245-254. |
| [7] | 杨赛,黄可龙,刘素琴,王海波.LiFePO4在饱和LiNO3溶液中的锂化行为[J].无机化学学报,2007(01):141-144. |
| [8] | 黄可龙,杨赛,刘素琴,王海波.磷酸铁锂在饱和硝酸锂溶液中的电极过程动力学[J].物理化学学报,2007(01):129-133. |
| [9] | Li W;Dahn J R;Wainwright D S .Rechargeable lithium batteries with aqueous electrolytes[J].Science,1994,264(5162):1115-1118. |
| [10] | Kohler J.;Uegaito H.;Inoue H.;Toki M.;Makihara H. .LiV3O8: characterization as anode material for an aqueous rechargeable Li-ion battery system[J].Electrochimica Acta,2000(1):59-65. |
| [11] | G.J. Wang;Q.T.Qu;B. Wang;Y. Shi;S. Tian;Y.P. Wu;R. Holze .Electrochemical intercalation of lithium ions into LiV_3O_8 in an aqueous electrolyte[J].Journal of Power Sources,2009(1):503-506. |
| [12] | Mingshu Zhao;Bao Zhang;Guanliang Huang;Hanyuan Zhang;Xiaoping Song .Excellent rate capabilities of (LiFePO_4/C)//LiV_3O_8 in an optimized aqueous solution electrolyte[J].Journal of Power Sources,2013(Jun.15):181-186. |
| [13] | 刘黎,田方华,王先友,周萌.LiV3O8在Li2SO4水溶液中的电化学性能[J].物理化学学报,2011(11):2600-2604. |
| [14] | Wang GJ;Zhang HP;Fu LJ;Wang B;Wu YP .Aqueous rechargeable lithium battery (ARLB) based on LiV3O8 and LiMn2O4 with good cycling performance[J].Electrochemistry communications,2007(8):1873-1876. |
| [15] | Gaojun Wang;Lijun Fu;Nahong Zhao;Lichun Yang;Yuping Wu;Haoqing Wu .An Aqueous Rechargeable Lithium Battery with Good Cycling Performance[J].Angewandte Chemie,2007(26):295-297. |
| [16] | G. J. Wang;N. H. Zhao;L. C. Yang;Y. P. Wu;H. Q. Wu;R. Holze .Characteristics of an aqueous rechargeable lithium battery (ARLB)[J].Electrochimica Acta,2007(15):4911-4915. |
| [17] | Yadegari, H.;Jabbari, A.;Heli, H. .An aqueous rechargeable lithium-ion battery based on LiCoO _2 nanoparticles cathode and LiV _3O _8 nanosheets anode[J].Journal of solid state electrochemistry,2012(1):227-234. |
| [18] | Mingshu Zhao;Guanliang Huang;Bao Zhang;Fei Wang;Xiaoping Song .Characteristics and electrochemical performance of LiFe_(0.5)Mn_(0.5)PO_4/C used as cathode for aqueous rechargeable lithium battery[J].Journal of Power Sources,2012(Aug.1):202-207. |
| [19] | Wang G J;Fu L J;Wang B et al.An aqueous re-chargeable lithium battery based on LiV3 O8 and LiNi1/3 Co1/3 Mn1/3 O2[J].Journal of Applied Electrochemistry,2008,38(04):579-581. |
| [20] | Lei Tian;Anbao Yuan .Electrochemical performance of nanostructured spinel LiMn_2O_4 in different aqueous electrolytes[J].Journal of Power Sources,2009(2):391-395. |
| [21] | Wang YG;Luo JY;Wang CX;Xia YY .Hybrid aqueous energy storage cells using activated carbon and lithium-ion intercalated compounds II. Comparison of LiMn2O4, LiCo1/3Ni1/3Mn1/3O2, and LiCoO2 positive electrodes[J].Journal of the Electrochemical Society,2006(8):A1425-A1431. |
| [22] | Ping He;Jin-Long Liu;Wang-Jun Cui;Jia-Yan Luo;Yong-Yao Xia .Investigation on capacity fading of LiFePO_4 in aqueous electrolyte[J].Electrochimica Acta,2011(5):2351-2357. |
| [23] | Liu, L.;Tian, F.;Yang, Z.;Zhou, M.;Wang, X. .Electrochemical behavior of nanostructured LiV_3O_8 in aqueous LiNO_3 solution[J].The journal of physics and chemistry of solids,2011(12):1495-1500. |
| [24] | C. Cheng;Z. H. Li;X. Y. Zhan;Q. Z. Xiao;G. T. Lei;X. D. Zhou .A macaroni-like Li_(1.2)V_3O_8 nanomaterial with high capacity for aqueous rechargeable lithium batteries[J].Electrochimica Acta,2010(15):4627-4631. |
| [25] | Ivana Stojkovic;Nikola Cvjeticanin;Miodrag Mitric;Slavko Mentus .Electrochemical properties of nanostructured Li_(1.2)V_3O_8 in aqueous LiNO_3 solution[J].Electrochimica Acta,2011(18):6469-6473. |
| [26] | Heli H;Yadegari H;Jabbari A .Low-temperature syn-thesis of LiV3 O8 nanosheets as an anode material with high power density for aqueous lithium-ion batteries[J].Materials Chemistry and Physics,2011,126(03):476-479. |
| [27] | Mingshu Zhao;Qingyang Zheng;Fei Wang;Weimin Dai;Xiaoping Song .Electrochemical performance of high specific capacity of lithium-ion cell LiV_3O_8//LiMn_2O_4 with LiNO_3 aqueous solution electrolyte[J].Electrochimica Acta,2011(11):3781-3784. |
| [28] | 谭帅,孙旦,王海燕,侯天丽,肖仲星,唐有根.片状LiV3O8软模板辅助溶胶-凝胶法制备及其在水系锂离子电池中的性能研究[J].电化学,2013(06):579-584. |
| [29] | Jian Bao;Min Zhou;Yongquan Zeng .Li_(0.3)V2O5 with high lithium diffusion rate: a promising anode material for aqueous lithium-ion batteries with superior rate performance[J].Journal of Materials Chemistry, A. Materials for energy and sustainability,2013(17):5423-5429. |
| [30] | Haibo Wang;Yuqun Zeng;Kelong Huang;Suqin Liu;Liquan Chen .Improvement of cycle performance of lithium ion cell LiMn{sub}2O{sub}4/Il{sub}xV{sub}2O{sub}5 with aqueous solution electrolyte by polypyrrole coating on anode[J].Electrochimica Acta,2007(15):5102-5107. |
| [31] | Pasquali M;Pistoia G .Lithium intercalation in Na1+x V3 O8 synthesized by a solution technique[J].Electrochimica Acta,1991,36(10):1549-1553. |
| [32] | Kawakita Jin;Kishi Tomiya;Miura Takashi .Comparison of Na_(1+x)V_3O_8 with Li_(1+x)V_3O_8 as lithium insertion host[J].Solid state ionics,1999(1/4):21-28. |
| [33] | Haiyan Wang;Wenjie Wang;Yu Ren;KelongHuang;Suqin Liu .A new cathode material Na_2V_6O_(16)·xH_2O nanowire for lithium ion battery[J].Journal of Power Sources,2012(Feb.1):263-269. |
| [34] | Donghui Zhou;Suqin Liu;Haiyan Wang;Guiqing Yan .Na_2V_6O_(16)·0.14H_2O nanowires as a novel anode material for aqueous rechargeable lithium battery with good cycling performance[J].Journal of Power Sources,2013(Apr.1):111-117. |
| [35] | Wang, W.;Wang, H.;Liu, S.;Huang, J. .Synthesis of γ-LiV _2O _5 nanorods as a high-performance cathode for Li ion battery[J].Journal of solid state electrochemistry,2012(7):2555-2561. |
| [36] | Zhou G T;Wang X;Yu J C .Selected-control synthesis of NaV6O15 and Na2V6O16@3H2O single-crystalline nanowires[J].Crystal Growth and Design,2004,5(07):969-974. |
| [37] | Xu Y;Han X;Zheng L et al.Pillar effect on cyclabili-ty enhancement for aqueous lithium ion batteries:a new material of β-vanadium bronze M0.33 V2 O5(M=Ag, Na)nanowires[J].Journal of Materials Chemistry,2011,21(38):14466-14472. |
| [38] | Chirayil T.;Whittingham MS.;Zavalij PY. .Hydrothermal synthesis of vanadium oxides [Review][J].Chemistry of Materials,1998(10):2629-2640. |
| [39] | Oka Y;Yao T;Yamamoto N .Structure determination of H2 V3 O8 by powder X-ray diffraction[J].Journal of Solid State Chemistry,1990,89(02):372-377. |
| [40] | Baudrin E;Sudant G;Larcher D;Dunn B;Tarascon JM .Preparation of nanotextured VO2[B] from vanadium oxide aerogels[J].Chemistry of Materials: A Publication of the American Chemistry Society,2006(18):4369-4374. |
| [41] | Huiqiao Li;Tianyou Zhai;Ping He .Single-crystal H2V3O8 nanowires: a competitive anode with large capacity for aqueous lithium-ion batteries[J].Journal of Materials Chemistry: An Interdisciplinary Journal dealing with Synthesis, Structures, Properties and Applications of Materials, Particulary Those Associated with Advanced Technology,2011(6):1780-1787. |
| [42] | Jia-Yan Luo;Wang-Jun Cui;Ping He .Raising the cycling stability of aqueous lithium-ion batteries by eliminating oxygen in the electrolyte[J].Nature Chemistry,2010(9):761-765. |
| [43] | Wang Y;Yi J;Xia Y .Recent progress in aqueous lithi-um-ion batteries[J].Advanced Energy Materials,2012,2(07):830-840. |
| [44] | Wang H;Huang K;Zeng Y et al.Stabilizing cyclabili-ty of an aqueous lithium-ion battery LiNi1/3 Co1/3 O2/Lix V2 O5 by polyaniline coating on the anode[J].Elec-trochemical and Solid State Letters,2007,10(09):A199-A203. |
| [45] | Electrochemical instability of LiV_3O_8 as an electrode material for aqueous rechargeable lithium batteries[J].Journal of Power Sources,2010(13):p.4318. |
| [46] | L.L. Liu;X.J. Wang;Y.S. Zhu;C.L. Hu;Y.P. Wu;R. Holze .Polypyrrole-coated LiV_3O_8-nanocomposites with good electrochemical performance as anode material for aqueous rechargeable lithium batteries[J].Journal of Power Sources,2013(Feb.15):290-294. |
| [47] | Liu L;Zhou M;Wang X et al.Improvement of elec-trochemical properties of LiV3 O8/LiMn2 O4 ARLB by NiO nanofibers coating on the anode[J].Journal of the Electrochemical Society,2012,159(08):A1230-A1235. |
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