Superior wide-temperature lithium storage in a porous cobalt vanadate

Wang, Z. L.; Xu, D.; Wang, L. M.; Zhang, X. B. Facile and low-cost synthesis of large-area pure V2O5 nanosheets for high-capacity and high-rate lithium storage over a wide temperature range. ChemPlusChem2012, 77, 124–128.

Xu, G. J.; Huang, S. Q.; Cui, Z. L.; Du, X. F.; Wang, X.; Lu, D.; Shangguan, X. H.; Ma, J.; Han, P. X.; Zhou, X. H. et al. Functional additives assisted ester-carbonate electrolyte enables wide temperature operation of a high-voltage (5 V-Class) Li-ion battery. J. Power Sources2019, 416, 29–36.

Kafle, J.; Harris, J.; Chang, J.; Koshina, J.; Boone, D.; Qu, D. Y. Development of wide temperature electrolyte for graphite/LiNiMnCoO2 Li-ion cells: High throughput screening. J. Power Sources2018, 392, 60–68.

Wang, J.; Nie, P.; Xu, G. Y.; Jiang, J. M.; Wu, Y. T.; Fu, R. R.; Dou, H.; Zhang, X. G. High-voltage LiNi0.45Cr0.1Mn1.45O4 cathode with superlong cycle performance for wide temperature lithium-ion batteries. Adv. Funct. Mater.2018, 28, 1704808.

Rodrigues, M. T. F.; Babu, G.; Gullapalli, H.; Kalaga, K.; Sayed, F. N.; Kato, K.; Joyner, J.; Ajayan, P. M. A materials perspective on Li-ion batteries at extreme temperatures. Nat. Energy2017, 2, 17108.

Lian, Q. W.; Zhou, G; Liu, J. T.; Wu, C.; Wei, W. F.; Chen, L. B.; Li, C. C. Extrinsic pseudocapacitve Li-ion storage of SnS anode via lithiation-induced structural optimization on cycling. J. Power Sources2017, 366, 1–8.

Chen, D.; Tan, H. T.; Rui, X. H.; Zhang, Q.; Feng, Y. Z.; Geng, H. B.; Li, C. C.; Huang, S. M.; Yu, Y. Oxyvanite V3O5: A new intercalation-type anode for lithium-ion battery. InfoMat2019, 1, 251–259.

Li, H.; Peng, L.; Wu, D. B.; Wu, J.; Zhu, Y. J.; Hu, X. L. Ultrahigh-capacity and fire-resistant LiFePO4-based composite cathodes for advanced lithium-ion batteries. Adv. Energy Mater.2019, 9, 1802930.

Tarascon, J. M.; Gozdz, A.; Schmutz, C.; Shokoohi, F.; Warren, P. Performance of Bellcore’s plastic rechargeable Li-ion batteries. Solid State Ionics1996, 86, 49–54.

Aurbach, D.; Talyosef, Y.; Markovsky, B.; Markevich, E.; Zinigrad, E.; Asraf, L.; Gnanaraj, J. S.; Kim, H. J. Design of electrolyte solutions for Li and Li-ion batteries: A review. Electrochim. Acta2004, 50, 247–254.

Jiang, Y.; Liu, Z. Y.; Matsuhisa, N.; Qi, D. P.; Leow, W. R.; Yang, H.; Yu, J. C.; Chen, G; Liu, Y. Q.; Wan, C. J. et al. Auxetic mechanical metamaterials to enhance sensitivity of stretchable strain sensors. Adv. Mater.2018, 30, 1706589.

Liu, F.; Chen, Z. X.; Fang, G. Z.; Wang, Z. Q.; Cai, Y. S.; Tang, B. Y.; Zhou, J.; Liang, S. Q. V2O5 nanospheres with mixed vanadium valences as high electrochemically active aqueous zinc-ion battery cathode. Nano-Micro Lett.2019, 11, 25.

Ji, W. X.; Wang, F.; Liu, D. T.; Qian, J. F.; Cao, Y. L.; Chen, Z. X.; Yang, H. X.; Ai, X. P. Building thermally stable Li-ion batteries using a temperature-responsive cathode. J. Mater. Chem. A2016, 4, 11239–11246.

Tang, B. Y.; Shan, L. T.; Liang, S. Q.; Zhou, J. Issues and opportunities facing aqueous zinc-ion batteries. Energy Environ. Sci.2019, in press, DOI: https://doi.org/10.1039/C9EE02526J .

Yang, Y. Q.; Tang, Y.; Fang, G. Z.; Shan, L. T.; Guo, J. S.; Zhang, W. Y.; Wang, C.; Wang, L. B.; Zhou, J.; Liang, S. Q. Li+ intercalated V2O5nH2O with enlarged layer spacing and fast ion diffusion as an aqueous zinc-ion battery cathode. Energy Environ. Sci.2018, 11, 3157–3162.

Zhang, S. S.; Xu, K.; Jow, T. R. A new approach toward improved low temperature performance of Li-ion battery. Electrochem. Commun.2002, 4, 928–932.

Qin, R. H.; Wei, Y. Q.; Zhai, T. Y.; Li, H. Q. LISICON structured Li3V2(PO4)3 with high rate and ultralong life for low-temperature lithium-ion batteries. J. Mater. Chem. A2018, 6, 9737–9746.

Liu, Y.; Yang, B. C.; Dong, X. L.; Wang, Y. G.; Xia, Y. Y. A simple prelithiation strategy to build a high-rate and long-life lithium-ion battery with improved low-temperature performance. Angew. Chem., Int. Ed.2017, 56, 16606–16610.

Chen, X. Z.; He, W. J.; Ding, L. X.; Wang, S. Q.; Wang, H. H. Enhancing interfacial contact in all solid state batteries with a cathode-supported solid electrolyte membrane framework. Energy Environ. Sci.2019, 12, 938–944.

Jiang, Z. Y.; Xie, H. Q.; Wang, S. Q.; Song, X.; Yao, X.; Wang, H. H. Perovskite membranes with vertically aligned microchannels for all-solidstate lithium batteries. Adv. Energy Mater.2018, 8, 1801433.

Xiang, H. F.; Chen, J. J.; Li, Z.; Wang, H. H. An inorganic membrane as a separator for lithium-ion battery. J. Power Sources2011, 196, 8651–8655.

Yin, Z. G.; Qin, J. W.; Wang, W.; Cao, M. H. Rationally designed hollow precursor-derived Zn3V2O8 nanocages as a high-performance anode material for lithium-ion batteries. Nano Energy2017, 31, 367–376.

Zhou, C. S.; Lu, J. M.; Hu, M. X.; Huang, Z. H.; Kang, F. Y.; Lv, R. T. High areal capacity Li-ion storage of binder-free metal vanadate/carbon hybrid anode by ion-exchange reaction. Small2018, 14, 1801832.

Lu, S. Y.; Zhu, T. X.; Li, Z. Y.; Pang, Y. C.; Shi, L.; Ding, S. J.; Gao, G. X. Ordered mesoporous carbon supported Ni3V2O8 composites for lithium-ion batteries with long-term and high-rate performance. J. Mater. Chem. A2018, 6, 7005–7013.

Liu, P. C.; Zhu, K. J.; Gao, Y. F.; Luo, H. J.; Lu, L. Recent progress in the applications of vanadium-based oxides on energy storage: From low-dimensional nanomaterials synthesis to 3D micro/nano-structures and free-standing electrodes fabrication. Adv. Energy Mater.2017, 7, 1700547.

Li, M. L.; Gao, Y.; Chen, N.; Meng, X.; Wang, C. Z.; Zhang, Y. Q.; Zhang, D.; Wei, Y. J.; Du, F.; Chen, G. Cu3V2O8 nanoparticles as intercalation-type anode material for lithium-ion batteries. Chem. Eur. J.2016, 22, 11405–11412.

Zhang, X.; Yang, W. W.; Liu, J. G.; Zhou, Y.; Feng, S. C.; Yan, S. C.; Yao, Y. F.; Wang, G.; Wan, L.; Fang, C. et al. Ultralong metahewettite CaV6O16·3H2O nanoribbons as novel host materials for lithium storage: Towards high-rate and excellent long-term cyclability. Nano Energy2016, 22, 38–47.

Wang, J. L.; Pei, J.; Hua, K.; Chen, D. H.; Jiao, Y.; Hu, Y. Y.; Chen, G. Synthesis of Co2V2O7 hollow cylinders with enhanced lithium storage properties using H2O2 as an etching agent. ChemElectroChem2018, 5, 737–742.

Chu, X. F.; Wang, H.; Chi, Y. D.; Wang, C.; Lei, L.; Zhang, W. T.; Yang, X. T. Hard-template-engaged formation of Co2V2O7 hollow prisms for lithium ion batteries. RSC Adv.2018, 8, 2072–2076.

Wu, F. F.; Yu, C. H.; Liu, W. X.; Wang, T.; Feng, J. K.; Xiong, S. L. Large-scale synthesis of Co2V2O7 hexagonal microplatelets under ambient conditions for highly reversible lithium storage. J. Mater. Chem. A2015, 3, 16728–16736.

Zhang, Q.; Pei, J.; Chen, G.; Bie, C. F.; Sun, J. X.; Liu, J. Porous Co3V2O8 nanosheets with ultrahigh performance as anode materials for lithium ion batteries. Adv. Mater. Interfaces2017, 4, 1700054.

Wu, F. F.; Xiong, S. L.; Qian, Y. T.; Yu, S. H. Hydrothermal synthesis of unique hollow hexagonal prismatic pencils of Co3V2O8·nH2O: A new anode material for lithium-ion batteries. Angew. Chem., Int. Ed.2015, 54, 10787–10791.

Luo, Y. Z.; Xu, X.; Zhang, Y. X.; Chen, C. Y.; Zhou, L.; Yan, M. Y.; Wei, Q. L.; Tian, X. C.; Mai, L. Q. Graphene oxide templated growth and superior lithium storage performance of novel hierarchical Co2V2O7 nanosheets. ACS Appl. Mater. Interfaces2016, 8, 2812–2818.

Wang, Y. C.; Chai, H.; Dong, H.; Xu, J. Y.; Jia, D. Z.; Zhou, W. Y. Superior cycle stability performance of quasi-cuboidal CoV2O6 microstructures as electrode material for supercapacitors. ACS Appl. Mater. Interfaces2016, 8, 27291–27297.

Zhang, W. Y.; Fu, Y. S.; Liu, W. W.; Lim, L.; Wang, X.; Yu, A. P. A general approach for fabricating 3D MFe2O4 (M = Mn, Ni, Cu, Co)/graphitic carbon nitride covalently functionalized nitrogen-doped graphene nanocomposites as advanced anodes for lithium-ion batteries. Nano Energy2019, 57, 48–56.

Sambandam, B.; Soundharrajan, V.; Mathew, V.; Song, J. J.; Kim, S.; Jo, J.; Tung, D. P.; Kim, S.; Kim, J. Metal-organic framework-combustion: A new, cost-effective and one-pot technique to produce a porous Co3V2O8 microsphere anode for high energy lithium ion batteries. J. Mater. Chem. A2016, 4, 14605–14613.

Soundharrajan, V.; Sambandam, B.; Song, J. J.; Kim, S.; Jo, J.; Kim, S.; Lee, S.; Mathew, V.; Kim, J. Co3V2O8 sponge network morphology derived from metal-organic framework as an excellent lithium storage anode material. ACS Appl. Mater. Interfaces2016, 8, 8546–8553.

Jiang, T. C.; Bu, F. X.; Feng, X. X.; Shakir, I.; Hao, G. L.; Xu, Y. X. Porous Fe2O3 nanoframeworks encapsulated within three-dimensional graphene as high-performance flexible anode for lithium-ion battery. ACS Nano2017, 11, 5140–5147.

Yao, X.; Zhao, Y. L. Three-dimensional porous graphene networks and hybrids for lithium-ion batteries and supercapacitors. Chem2017, 2, 171–200.

Jung, H. G.; Jang, M. W.; Hassoun, J.; Sun, Y. K.; Scrosati, B. A high-rate long-life Li4Ti5O12/Li[Ni0.45Co0.1Mn1.45]O4 lithium-ion battery. Nat. Commun.2011, 2, 516.

Chen, D.; Rui, X. H.; Zhang, Q.; Geng, H. B.; Gan, L. Y.; Zhang, W.; Li, C. C.; Huang, S. M.; Yu, Y. Persistent zinc-ion storage in mass-produced V2O5 architectures. Nano Energy2019, 60, 171–178.

Chao, D. L.; Xia, X. H.; Liu, J. L.; Fan, Z. X.; Ng, C. F.; Lin, J. Y.; Zhang, H.; Shen, Z. X.; Fan, H. J. A V2O5/conductive-polymer core/shell nanobelt array on three-dimensional graphite foam: A high-rate, ultrastable, and freestanding cathode for lithium-ion batteries. Adv. Mater.2014, 26, 5794–5800.

Yang, G. Z.; Cui, H.; Yang, G. W.; Wang, C. X. Self-Assembly of Co3V2O8 multilayered nanosheets: Controllable synthesis, excellent Li-storage properties, and investigation of electrochemical mechanism. ACS Nano2014, 8, 4474–4487.

Lv, C. D.; Sun, J. X.; Chen, G.; Yan, C. S.; Chen, D. H. Achieving Ni3V2O8 amorphous wire encapsulated in crystalline tube nanostructure as anode materials for lithium ion batteries. Nano Energy2017, 33, 138–145.

Zhu, C.; Liu, Z. Q.; Wang, J.; Pu, J.; Wu, W. L.; Zhou, Q. W.; Zhang, H. G. Novel Co2VO4 anodes using ultralight 3D metallic current collector and carbon sandwiched structures for high-performance Li-ion batteries. Small2017, 13, 1701260.

Zhang, L.; Zhao, K. N.; Luo, Y. Z.; Dong, Y. F.; Xu, W. W.; Yan, M. Y.; Ren, W. H.; Zhou, L.; Qu, L. B.; Mai, L. Q. Acetylene black induced heterogeneous growth of macroporous CoV2O6 nanosheet for high-rate pseudocapacitive lithium-ion battery anode. ACS Appl. Mater. Interfaces2016, 8, 7139–7146.

Ma, F. X.; Wu, H. B.; Xu, C. Y.; Zhen, L.; Lou, X. W. D. Self-organized sheaf-like Fe3O4/C hierarchical microrods with superior lithium storage properties. Nanoscale2015, 7, 4411–4414.

Zhang, D.; Li, G. S.; Li, B. Y.; Fan, J. M.; Liu, X. Q.; Chen, D. D.; Li, L. P. A facile strategy to fabricate V2O3/porous N-doped carbon nanosheet framework as high-performance anode for lithium-ion batteries. J. Alloys Compd.2019, 789, 288–294.

Feng, Y. H.; Chen, S. H.; Wang, J.; Lu, B. G. Carbon foam with microporous structure for high performance symmetric potassium dual-ion capacitor. J. Energy Chem.2020, 43, 129–138.

Wang, T.; Zhu, J.; Wei, Z. X.; Yang, H. G.; Ma, Z. L.; Ma, R. F.; Zhou, J.; Yang, Y. H.; Peng, L. L.; Fei, H. L. et al. Bacteria derived biological carbon building robust Li-S batteries. Nano lett.2019, 19, 4384–4390.

Wen, W.; Wu, J. M.; Jiang, Y. Z.; Lai, L. L.; Song, J. Pseudocapacitance-enhanced Li-ion microbatteries derived by a TiN@TiO2 nanowire anode. Chem2017, 2, 404–416.