[2] [2] WANG J H, YAMADA Y, SODEYAMA K, et al. Fire-extinguishing organic electrolytes for safe batteries[J].Nature Energy, 2018,3(1): 22-29.

[3] [3] WU W F, YAN X B, ZHAN Y. Recent progress of electrolytes and electrocatalysts in neutral aqueous zinc-air batteries[J].Chemical Engineering Journal, 2023,451: 138608.

[4] [4] LIU J L, XU C H, CHEN Z, et al. Progress in aqueous rechargeable batteries[J].Green Energy & Environment, 2018,3(1): 20-41.

[5] [5] CHAO D L, ZHU C, SONG M, et al. A high-rate and stable quasi-solid-state zinc-ion battery with novel 2D layered zinc orthovanadate array[J].Advanced Materials, 2018,30(32): 1803181.

[6] [6] LIU N, LI B, HE Z X, et al. Recent advances and perspectives on vanadium-and manganese-based cathode materials for aqueous zinc ion batteries[J].Journal of Energy Chemistry, 2021,59: 134-159.

[7] [7] GUO C, YI S J, SI R, et al. Advances on defect engineering of vanadium-based compounds for high-energy aqueous zinc-ion batteries[J].Advanced Energy Materials, 2022,12(40): 2202039.

[8] [8] DU W C, ANG E H X, YANG Y, et al. Challenges in the material and structural design of zinc anode towards high-performance aqueous zinc-ion batteries[J].Energy & Environmental Science, 2020,13(10): 3330-3360.

[9] [9] SONG M, TAN H, CHAO D L, et al. Recent advances in Zn-ion batteries[J].Advanced Functional Materials, 2018,28(41): 1802564.

[10] [10] CHAO D L, ZHOU W H, XIE F X, et al. Roadmap for advanced aqueous batteries: From design of materials to applications[J].Science Advances, 2020,6(21): eaba4098.

[11] [11] TANG B Y, ZHOU J, FANG G Z, et al. Engineering the interplanar spacing of ammonium vanadates as a high-performance aqueous zinc-ion battery cathode[J].Journal of Materials Chemistry A, 2019,7(3): 940-945.

[12] [12] XU Y, FAN G L, SUN P X, et al. Carbon nitride pillared vanadate via chemical pre-intercalation towards high-performance aqueous zinc-ion batteries[J].Angewandte Chemie-International Edition, 2023,62(26): e202303529.

[13] [13] CAO J, ZHANG D D, YUE Y L, et al. Oxygen defect enriched (NH4)2V10O25·8H2O nanosheets for superior aqueous zinc-ion batteries[J].Nano Energy, 2021,84: 105876.

[14] [14] WANG X, XI B J, FENG Z Y, et al. Layered (NH4)2V6O16·1.5H2O nanobelts as a high-performance cathode for aqueous zinc-ion batteries[J].Journal of Materials Chemistry A, 2019,7(32): 19130-19139.

[15] [15] WANG X R, WANG Y L, Naveed A, et al. Magnesium ion doping and micro-structural engineering assist NH4V4O10 as a high-performance aqueous zinc ion battery cathode[J].Advanced Functional Materials, 2023,33(48): 2306205.

[16] [16] CUI F H, WANG D S, HU F, et al. Deficiency and surface engineering boosting e lectronic and ionic kinetics in NH4V4O10 for high-performance aqueous zinc-ion battery[J].Energy Storage Materials, 2022,44: 197-205.

[17] [17] ZHENG Y, TIAN C X, WU Y T, et al. Dual-engineering of ammonium vanadate for enhanced aqueous and quasi-solid-state zinc ion batteries[J].Energy Storage Materials, 2022,52: 664-674.

[18] [18] ZONG Q, DU W, LIU C F, et al. Enhanced reversible zinc ion intercalation in deficient ammonium vanadate for high-performance aqueous zinc-ion battery[J].Nano-Micro Letters, 2021,13(1): 116.

[19] [19] CHEN L M, YUE H F, ZHANG Z Q, et al. Pre-removing partial ammonium ions from the interlayer of ammonium vanadate with acid treating for quasi-solid-state flexible zinc ion batteries[J].Chemical Engineering Journal, 2023,455: 140679.

[20] [20] WANG X R, NAVEED A, ZENG T Y, et al. Sodium ion stabilized ammonium vanadate as a high-performance aqueous zinc-ion battery cathode[J].Chemical Engineering Journal, 2022,446: 137090.

[21] [21] WANG K, YUAN R L, LI M J, et al. Al3+ intercalated NH4V4O10 nanosheet on carbon cloth for high-performance aqueous zinc-ion batteries[J].Chemical Engineering Journal, 2023,471: 144655.

[22] [22] HE T, WENG S T, YE Y S, et al. Cation-deficient Zn0.3(NH4)0.3V4O10·0.91H2O for rechargeable aqueous zinc battery with superior low-temperature performance[J].Energy Storage Materials, 2021,38: 389-396.

[23] [23] ZONG Q, WANG Q Q, LIU C F, et al. Potassium ammonium vanadate with rich oxygen vacancies for fast and highly stable Zn-ion storage[J].ACS nano, 2022,16(3): 4588-4598.

[24] [24] ZHANG L, WANG R R, WANG M J, et al. Dual-defect modulating potassium anchored NH4V4O10 for stable high-energy aqueous zinc-ion batteries[J].Chemical Engineering Journal, 2023,475: 146127.

[25] [25] LIU Y N, XU M W, SHEN B L, et al. Facile synthesis of mesoporous NH4V4O10 nanoflowers with high performance as cathode material for lithium battery[J].Journal of Materials Science, 2018,53(3): 2045-2053.

[26] [26] LIU C F, ZHANG Y, CHENG H H, et al. “Dual-engineering” strategy to regulate NH4V4O10 as cathodes for high-performance aqueous zinc ion batteries[J].Small, 2023,19(39): 2301870.

[27] [27] ZONG Q, ZHUANG Y L, LIU C F, et al. Dual effects of metal and organic ions co-intercalation boosting the kinetics and stability of hydrated vanadate cathodes for aqueous zinc-ion batteries[J].Advanced Energy Materials, 2023,13(31): 2301480.

[28] [28] TIAN M, LIU C F, ZHENG J Q, et al. Structural engineering of hydrated vanadium oxide cathode by K+ incorporation for high-capacity and long-cycling aqueous zinc ion batteries[J].Energy Storage Materials, 2020,29: 9-16.

[29] [29] FENG Z Y, ZHANG Y F, SUN JJ, et al. Dual ions enable vanadium oxide hydration with superior Zn2+ storage for aqueous zinc-ion batteries[J].Chemical Engineering Journal, 2022,433: 133795.

[30] [30] CHEN J, SU L P, ZHANG X Q, et al. Ethylene glycol intercalation engineered interplanar spacing and redox activity of ammonium vanadate nanoflowers as a high-performance cathode for aqueous zinc-ion batteries[J].Acs Sustainable Chemistry & Engineering, 2023,11(33): 12467-12476.

[31] [31] PENG Y Q, MO L E, WEI T T, et al. Oxygen vacancies on NH4V4O10 accelerate ion and charge transfer in aqueous zinc-ion batteries[J].Small, 2024,20(11): 2306972.

[32] [32] LI S J, XU X Y, CHEN W X, et al. Synergetic impact of oxygen and vanadium defects endows NH4V4O10 cathode with superior performances for aqueous zinc-ion battery[J].Energy Storage Materials, 2024,65: 103108.

[33] [33] LI Y T, ZHANG S, WANG S T, et al. Layered structure regulation for zinc-ion batteries: Rate capability and cyclability enhancement by rotatable pillars[J].Advanced Energy Materials, 2023,13(16): 2203810.

[34] [34] LI S Y, YU D X, LIU J Y, et al. Quantitative regulation of interlayer space of NH4V4O10 for fast and durable Zn andNH4+ Storage[J].Advanced Science, 2023,10(9): 2206836.

[35] [35] LIU X, XU G B, ZHANG Q, et al. Ultrathin hybrid nanobelts of single-crystalline VO2 and poly (3,4-ethylenedioxythiophene) as cathode materials for aqueous zinc ion batteries with large capacity and high-rate capability[J].Journal of Power Sources, 2020,463: 228223.

[36] [36] PANG Q, SUN C L, YU Y H, et al. H2V3O8 nanowire/graphene electrodes for aqueous rechargeable zinc ion batteries with high rate capability and large capacity[J].Advanced Energy Materials, 2018,8(19): 1800144.

[37] [37] JIAO T P, YANG Q, WU S L, et al. Binder-free hierarchical VS2 electrodes for high-performance aqueous Zn ion batteries towards commercial level mass loading[J].Journal of Materials Chemistry A, 2019,7(27): 16330-16338.

[38] [38] WEI R C, WANG X, XI B J, et al. Layer-by-layer stacked (NH4)2V4O9·0.5H2O nanosheet assemblies with intercalation pseudocapacitance for high rate aqueous zinc ion storage[J].ACS Applied Energy Materials, 2020,3(6): 5343-5352.

[39] [39] GENG H B, CHENG M, WANG B, et al. Electronic structure regulation of layered vanadium oxide via interlayer doping strategy toward superior high-rate and low-temperature zinc-ion batteries[J].Advanced Functional Materials, 2020,30(6): 1907684.

[40] [40] WANG L L, HUANG K W, CHEN J T, et al. Ultralong cycle stability of aqueous zinc-ion batteries with zinc vanadium oxide cathodes[J].Science Advances, 2019,5(10): eaax4279.