Page 48 - Read Online

P. 48

Page 30 of 31 Miao et al. Energy Mater 2023;3:300014 https://dx.doi.org/10.20517/energymater.2022.89

acid additive. Energy Stor Mater 2022;45:777-85. DOI
135. Zhang L, Miao L, Xin W, Peng H, Yan Z, Zhu Z. Engineering zincophilic sites on Zn surface via plant extract additives for dendrite-
free Zn anode. Energy Stor Mater 2022;44:408-15. DOI
136. Qiu M, Sun P, Qin A, Cui G, Mai W. Metal-coordination chemistry guiding preferred crystallographic orientation for reversible zinc
anode. Energy Stor Mater 2022;49:463-70. DOI
137. Luo M, Wang C, Lu H, et al. Dendrite-free zinc anode enabled by zinc-chelating chemistry. Energy Stor Mater 2021;41:515-21. DOI
138. Lin Y, Hu Y, Zhang S, et al. Highly reversible aqueous zinc-ion battery using the chelating agent triethanolamine as an electrolyte
additive. CrystEngComm 2022;24:7950-61. DOI
139. Han D, Sun T, Du H, et al. Controlling horizontal growth of zinc platelet by OP-10 additive for dendrite-free aqueous zinc-ion
batteries. Batteries Supercaps 2022;5:e202200219. DOI
140. Qiu M, Sun P, Wang Y, Ma L, Zhi C, Mai W. Anion-trap engineering toward remarkable crystallographic reorientation and efficient
cation migration of Zn Ion batteries. Angew Chem Int Ed 2022;61:e202210979. DOI PubMed
141. Yang J, Zhang Y, Li Z, et al. Three birds with one stone: tetramethylurea as electrolyte additive for highly reversible Zn-metal anode.
Adv Funct Mater 2022;32:2209642. DOI
142. Qian L, Yao W, Yao R, et al. Cations coordination-regulated reversibility enhancement for aqueous Zn-ion battery. Adv Funct Mater
2021;31:2105736. DOI
143. Huang H, Xie D, Zhao J, et al. Boosting reversibility and stability of Zn anodes via manipulation of electrolyte structure and interface
with addition of trace organic molecules. Adv Energy Mater 2022;12:2202419. DOI
144. Zhao K, Liu F, Fan G, et al. Stabilizing zinc electrodes with a vanillin additive in mild aqueous electrolytes. ACS Appl Mater
Interfaces 2021;13:47650-8. DOI PubMed
145. Meng Q, Zhao R, Cao P, et al. Stabilization of Zn anode via a multifunctional cysteine additive. Chem Eng J 2022;447:137471. DOI
146. Wang H, Li H, Tang Y, et al. Stabilizing Zn anode interface by simultaneously manipulating the thermodynamics of Zn nucleation
and overpotential of hydrogen evolution. Adv Funct Mater 2022;32:2207898. DOI
147. Wang B, Zheng R, Yang W, et al. Synergistic solvation and interface regulations of eco-friendly silk peptide additive enabling stable
aqueous zinc-ion batteries. Adv Funct Mater 2022;32:2112693. DOI
148. Ren H, Li S, Wang B, et al. Molecular-crowding effect mimicking cold-resistant plants to stabilize the zinc anode with wider service
temperature range. Adv Mater 2023;35:e2208237. DOI PubMed
149. Wang K, Qiu T, Lin L, Liu X, Sun X. A low fraction electrolyte additive as interface stabilizer for Zn electrode in aqueous batteries.
Energy Stor Mater 2023;54:366-73. DOI
150. Xie K, Ren K, Sun C, et al. Toward stable zinc-ion batteries: use of a chelate electrolyte additive for uniform zinc deposition. ACS
Appl Energy Mater 2022;5:4170-8. DOI
151. Zhang Y, Peng C, Zeng Z, et al. Sustainable phytic acid-zinc anticorrosion interface for highly reversible zinc metal anodes. ACS
Appl Mater Interfaces 2022;14:10419-27. DOI PubMed
152. Zhao F, Jing Z, Guo X, et al. Trace amounts of fluorinated surfactant additives enable high performance zinc-ion batteries. Energy
Stor Mater 2022;53:638-45. DOI
153. Liu B, Wei C, Zhu Z, et al. Regulating surface reaction kinetics through ligand field effects for fast and reversible aqueous zinc
batteries. Angew Chem Int Ed 2022;61:e202212780. DOI PubMed
154. Lu H, Zhang X, Luo M, et al. Amino acid-induced interface charge engineering enables highly reversible Zn anode. Adv Funct Mater
2021;31:2103514. DOI
155. Huang C, Zhao X, Liu S, et al. Stabilizing zinc anodes by regulating the electrical double layer with saccharin anions. Adv Mater
2021;33:e2100445. DOI PubMed
156. Qiu M, Ma L, Sun P, Wang Z, Cui G, Mai W. Manipulating interfacial stability via absorption-competition mechanism for long-
lifespan Zn anode. Nanomicro Lett 2021;14:31. DOI PubMed PMC
157. Hashemi A, Kasiri G, La Mantia F. The effect of polyethyleneimine as an electrolyte additive on zinc electrodeposition mechanism in
aqueous zinc-ion batteries. Electrochim Acta 2017;258:703-8. DOI
158. Zhang Y, Zheng X, Wu K, et al. Nonionic surfactant-assisted in situ generation of stable passivation protective layer for highly stable
aqueous Zn metal anodes. Nano Lett 2022;22:8574-83. DOI PubMed
159. Yuan W, Ma G, Nie X, et al. In-situ construction of a hydroxide-based solid electrolyte interphase for robust zinc anodes. Chem Eng
J 2022;431:134076. DOI
160. Yang M, Zhu J, Bi S, Wang R, Niu Z. A binary hydrate-melt electrolyte with acetate-oriented cross-linking solvation shells for stable
zinc anodes. Adv Mater 2022;34:e2201744. DOI PubMed
2+ +
161. Wang C, Sun L, Li M, et al. Aqueous Zn /Na dual-salt batteries with stable discharge voltage and high columbic efficiency by
systematic electrolyte regulation. Sci China Chem 2022;65:399-407. DOI
162. Guo X, Zhang Z, Li J, et al. Alleviation of dendrite formation on zinc anodes via electrolyte additives. ACS Energy Lett 2021;6:395-
403. DOI
3+
2+
163. Li H, Firby CJ, Elezzabi AY. Rechargeable aqueous hybrid Zn /Al electrochromic batteries. Joule 2019;3:2268-78. DOI
164. Cao J, Zhang D, Chanajaree R, et al. Stabilizing zinc anode via a chelation and desolvation electrolyte additive. Adv Powder Mater
2022;1:100007. DOI
165. Zhang S, Hao J, Luo D, et al. Dual-function electrolyte additive for highly reversible Zn anode. Adv Energy Mater 2021;11:2102010.

43 44 45 46 47 48 49 50 51 52 53