[1] [1] LI X Y, WANG L, FU Y H, et al. Optimization strategies toward advanced aqueous zinc-ion batteries: From facing key issues to viable solutions[J]. Nano Energy, 2023, 116: 108858.

[2] [2] YU X Y, LI Z G, WU X H, et al. Ten concerns of Zn metal anode for rechargeable aqueous zinc batteries[J]. Joule, 2023, 7(6): 1145-1175.

[3] [3] CHEN Jiahang, LI Tingting, NAVEED A, et al. J Chin Ceram Soc, 2020, 48(7): 1003-1012.

[4] [4] ZHAO Y, ZHOU R K, SONG Z H, et al. Interfacial designing of MnO2 half-wrapped by aromatic polymers for high-performance aqueous zinc-ion batteries[J]. Angew Chem Int Ed Engl, 2022, 61(49): e202212231.

[5] [5] YANG Q, LI Q, LIU Z X, et al. Dendrites in Zn-based batteries[J]. Adv Mater, 2020, 32(48): e2001854.

[6] [6] DAI Yuhang, GAN Zhiwei, RUAN Yushan, et al. J Chin Ceram Soc, 2021, 49(7): 1323-1336.

[7] [7] LIU Jiahao, HE Pingge, FAN Lizhen. J Chin Ceram Soc, 2020, 48(7): 990-1002.

[8] [8] NA M, SINGH V, CHOI R H, et al. Zn glutarate protective layers in situ form on Zn anodes for Zn redox flow batteries[J]. Energy Storage Mater, 2023, 57: 195-204.

[9] [9] HAN D L, WANG Z X, LU H T, et al. A self-regulated interface toward highly reversible aqueous zinc batteries[J]. Adv Energy Mater, 2022, 12(9): 2102982.

[10] [10] LI Shangying, WANG Chunyuan, WEI Wenfei, et al. J Chin Ceram Soc, 2023, 51(10): 2617-2625.

[11] [11] JIAN Q P, WANG T S, SUN J, et al. Hydrated solvation suppression of zinc ions for highly reversible zinc anodes[J]. Chem Eng J, 2023, 466: 143189.

[12] [12] MA G Q, MIAO L C, DONG Y, et al. Reshaping the electrolyte structure and interface chemistry for stable aqueous zinc batteries[J]. Energy Storage Mater, 2022, 47: 203-210.

[13] [13] MIAO L C, WANG R H, XIN W L, et al. Three-functional ether-based co-solvents for suppressing water-induced parasitic reactions in aqueous Zn-ion batteries[J]. Energy Storage Mater, 2022, 49: 445-453.

[14] [14] CHEN Y W, MA D T, OUYANG K F, et al. A multifunctional anti-proton electrolyte for high-rate and super-stable aqueous Zn-vanadium oxide battery[J]. Nanomicro Lett, 2022, 14(1): 154.

[15] [15] CORA S, AHMAD S, SA N Y. In situ probing of mass exchange at the solid electrolyte interphase in aqueous and nonaqueous Zn electrolytes with EQCM-D[J]. ACS Appl Mater Interfaces, 2021, 13(8): 10131-10140.

[16] [16] LI J, JIN Z, CHAO Y, et al. Synthesis of graphene-oxide-decorated porous ZnO nanosheet composites and their gas sensing properties[J]. Chemosensors, 2023, 11(1): 65.

[17] [17] EGASHIRA M. EQCM study on electrochemical zinc deposition- dissolution in water-In-salt electrolyte[J]. Electrochemistry, 2022, 90(5): 057001.

[18] [18] CHEN R W, ZHANG W, HUANG Q B, et al. Trace amounts of triple-functional additives enable reversible aqueous zinc-ion batteries from a comprehensive perspective[J]. Nanomicro Lett, 2023, 15(1): 81.

[19] [19] YANG J Z, YIN B S, SUN Y, et al. Zinc anode for mild aqueous zinc-ion batteries: Challenges, strategies, and perspectives[J]. Nanomicro Lett, 2022, 14(1): 42.

[20] [20] WAN T H, SACCOCCIO M, CHEN C, et al. Influence of the discretization methods on the distribution of relaxation times deconvolution: Implementing radial basis functions with DRTtools[J]. Electrochim Acta, 2015, 184: 483-499.

[21] [21] CIUCCI F, CHEN C. Analysis of electrochemical impedance spectroscopy data using the distribution of relaxation times: A Bayesian and hierarchical Bayesian approach[J]. Electrochim Acta, 2015, 167: 439-454.

[22] [22] HU Y Z, FU C Y, CHAI S M, et al. Construction of zinc metal-Tin sulfide polarized interface for stable Zn metal batteries[J]. Adv Powder Mater, 2023, 2(2): 100093.