Page 44 - Read Online

P. 44

Page 26 of 31 Miao et al. Energy Mater 2023;3:300014 https://dx.doi.org/10.20517/energymater.2022.89

14. Chen P, Yuan X, Xia Y, et al. An artificial polyacrylonitrile coating layer confining zinc dendrite growth for highly reversible
aqueous zinc-based batteries. Adv Sci 2021;8:e2100309. DOI PubMed PMC
15. Zhu Y, Cui Y, Alshareef HN. An anode-free Zn-MnO battery. Nano Lett 2021;21:1446-53. DOI
2
16. Wu J, Yuan C, Li T, Yuan Z, Zhang H, Li X. Dendrite-free zinc-based battery with high areal capacity via the region-induced
deposition effect of turing membrane. J Am Chem Soc 2021;143:13135-44. DOI PubMed
+ -
17. Dai Y, Li J, Chen L, et al. Generating H in catholyte and OH in anolyte: an approach to improve the stability of aqueous zinc-ion
batteries. ACS Energy Lett 2021;6:684-6. DOI
18. Yang W, Du X, Zhao J, et al. Hydrated eutectic electrolytes with ligand-oriented solvation shells for long-cycling zinc-organic
batteries. Joule 2020;4:1557-74. DOI
19. Zeng X, Hao J, Wang Z, Mao J, Guo Z. Recent progress and perspectives on aqueous Zn-based rechargeable batteries with mild
aqueous electrolytes. Energy Stor Mater 2019;20:410-37. DOI
20. Lv Y, Xiao Y, Ma L, Zhi C, Chen S. Recent advances in electrolytes for “beyond aqueous” zinc-ion batteries. Adv Mater
2022;34:e2106409. DOI PubMed
21. Geng Y, Pan L, Peng Z, et al. Electrolyte additive engineering for aqueous Zn ion batteries. Energy Stor Mater 2022;51:733-55. DOI
22. Cheng H, Sun Q, Li L, et al. Emerging era of electrolyte solvation structure and interfacial model in batteries. ACS Energy Lett
2022;7:490-513. DOI
23. Wang F, Borodin O, Gao T, et al. Highly reversible zinc metal anode for aqueous batteries. Nat Mater 2018;17:543-9. DOI PubMed
24. Xie J, Liang Z, Lu YC. Molecular crowding electrolytes for high-voltage aqueous batteries. Nat Mater 2020;19:1006-11. DOI
PubMed
25. Cui J, Liu X, Xie Y, et al. Improved electrochemical reversibility of Zn plating/stripping: a promising approach to suppress water-
induced issues through the formation of H-bonding. Mater Today Energy 2020;18:100563. DOI
26. Du H, Wang K, Sun T, et al. Improving zinc anode reversibility by hydrogen bond in hybrid aqueous electrolyte. Chem Eng J
2022;427:131705. DOI
27. Sun Y, Xu Z, Xu X, et al. Low-cost and long-life Zn/Prussian blue battery using a water-in-ethanol electrolyte with a normal salt
concentration. Energy Stor Mater 2022;48:192-204. DOI
28. Su Z, Chen J, Stansby J, et al. Hydrogen-bond disrupting electrolytes for fast and stable proton batteries. Small 2022;18:e2201449.
DOI PubMed
29. Miyake T, Rolandi M. Grotthuss mechanisms: from proton transport in proton wires to bioprotonic devices. J Phys Condens Matter
2016;28:023001. DOI PubMed
30. Chen X, Li HR, Shen X, Zhang Q. The origin of the reduced reductive stability of ion-solvent complexes on alkali and alkaline earth
metal anodes. Angew Chem Int Ed 2018;57:16643-7. DOI PubMed
31. Miao L, Wang R, Di S, et al. Aqueous electrolytes with hydrophobic organic cosolvents for stabilizing zinc metal anodes. ACS Nano
2022;16:9667-78. DOI PubMed
32. Yamada Y, Wang J, Ko S, Watanabe E, Yamada A. Advances and issues in developing salt-concentrated battery electrolytes. Nat
Energy 2019;4:269-80. DOI
33. Li C, Shyamsunder A, Hoane AG, et al. Highly reversible Zn anode with a practical areal capacity enabled by a sustainable
electrolyte and superacid interfacial chemistry. Joule 2022;6:1103-20. DOI
34. Collins KD, Washabaugh MW. The hofmeister effect and the behaviour of water at interfaces. Q Rev Biophys 1985;18:323-422. DOI
PubMed
35. Kim W, Kim H, Lee KM, et al. Demixing the miscible liquids: toward biphasic battery electrolytes based on the kosmotropic effect.
Energy Environ Sci 2022;15:5217-28. DOI
36. Zhang N, Cheng F, Liu Y, et al. Cation-deficient spinel ZnMn O cathode in Zn(CF SO ) electrolyte for rechargeable aqueous Zn-
2
3 2
3
4
ion battery. J Am Chem Soc 2016;138:12894-901. DOI
37. Geng Y, Miao L, Yan Z, et al. Super-zincophilic additive induced interphase modulation enables long-life Zn anodes at high current
density and areal capacity. J Mater Chem A 2022;10:10132-8. DOI
38. Gutmann V. Empirical parameters for donor and acceptor properties of solvents. Electrochim Acta 1976;21:661-70. DOI
39. Cao L, Li D, Hu E, et al. Solvation structure design for aqueous Zn metal batteries. J Am Chem Soc 2020;142:21404-9. DOI
PubMed
40. Hao J, Yuan L, Ye C, et al. Boosting zinc electrode reversibility in aqueous electrolytes by using low-cost antisolvents. Angew Chem
Int Ed 2021;60:7366-75. DOI PubMed
41. Chang N, Li T, Li R, et al. An aqueous hybrid electrolyte for low-temperature zinc-based energy storage devices. Energy Environ Sci
2020;13:3527-35. DOI
42. Shang Y, Kumar P, Musso T, et al. Long-life Zn anode enabled by low volume concentration of a benign electrolyte additive. Adv
Funct Mater 2022;32:2200606. DOI
43. Ma Q, Gao R, Liu Y, et al. Regulation of outer solvation shell toward superior low-temperature aqueous zinc-ion batteries. Adv Mater
2022;34:e2207344. DOI PubMed
2+
44. Wang N, Zhang Y, Yuan J, et al. A synergistic strategy of organic molecules introduced a high Zn flux solid electrolyte interphase
for stable aqueous zinc-ion batteries. ACS Appl Mater Interfaces 2022;14:48081-90. DOI PubMed
45. Wu Y, Zhu Z, Shen D, et al. Electrolyte engineering enables stable Zn-ion deposition for long-cycling life aqueous Zn-ion batteries.

39 40 41 42 43 44 45 46 47 48 49