Tuning Zn2+ coordination environment to suppress dendrite formation for high-performance Zn-ion batteries

“…We have demonstrated that a very simple and easily industrially applicable anode foil polishing process can dramatically improve the lifetime of ZIBs, far exceeding improvements made using complex chemical and physical processes. [14][15][16][17][18][19][20] The electrodes tested showed greatly improved electrochemical plating/ stripping stability, when compared to an as-received Zn foil. Ex situ OM and in situ EC-AFM experiments demonstrated that polished Zn foils with a attened initial surface induced a uniformly plated/stripped Zn structure, lowering the occurrence of dendrites and short-circuit failure in batteries.…”

“…10 In particular, it has been reported that the electrolyte composition and the current density at the electrode are major inuencers of dendrite morphology, 11 which can vary from a 1D ramied cone-like topology, to 2D hexagonal platelets and dense 3D structures. 12 Common strategies to achieve uniform Zn deposition include (1) introducing a protection layer on the electrode surface to help homogeneously distribute ions and the electric eld; 13,14 (2) optimizing the material and structure of the Zncontaining electrode, promoting charge transfer; 15,16 (3) modifying the electrolyte, improving interfacial ion migration; [17][18][19] and (4) designing multifunctional separators. 20 Example solutions using these strategies include (1) interfacial protection of the Zn anode by in situ growth of zeolitic imidazolate framework-8 (ZIF-8) layers; 14 (2) design of Zn/carbon nanotube (Zn/CNT) foams 15 or eutectic Zn 88 Al 12 (at%) alloys; 16 (3) electrolyte modifying additives 17,18 or use of high concentration electrolytes; 19 and (4) graphene decorated glass bre separators.…”

Dendrite suppression by anode polishing in zinc-ion batteries

“…We have demonstrated that a very simple and easily industrially applicable anode foil polishing process can dramatically improve the lifetime of ZIBs, far exceeding improvements made using complex chemical and physical processes. [14][15][16][17][18][19][20] The electrodes tested showed greatly improved electrochemical plating/ stripping stability, when compared to an as-received Zn foil. Ex situ OM and in situ EC-AFM experiments demonstrated that polished Zn foils with a attened initial surface induced a uniformly plated/stripped Zn structure, lowering the occurrence of dendrites and short-circuit failure in batteries.…”

“…10 In particular, it has been reported that the electrolyte composition and the current density at the electrode are major inuencers of dendrite morphology, 11 which can vary from a 1D ramied cone-like topology, to 2D hexagonal platelets and dense 3D structures. 12 Common strategies to achieve uniform Zn deposition include (1) introducing a protection layer on the electrode surface to help homogeneously distribute ions and the electric eld; 13,14 (2) optimizing the material and structure of the Zncontaining electrode, promoting charge transfer; 15,16 (3) modifying the electrolyte, improving interfacial ion migration; [17][18][19] and (4) designing multifunctional separators. 20 Example solutions using these strategies include (1) interfacial protection of the Zn anode by in situ growth of zeolitic imidazolate framework-8 (ZIF-8) layers; 14 (2) design of Zn/carbon nanotube (Zn/CNT) foams 15 or eutectic Zn 88 Al 12 (at%) alloys; 16 (3) electrolyte modifying additives 17,18 or use of high concentration electrolytes; 19 and (4) graphene decorated glass bre separators.…”

Dendrite suppression by anode polishing in zinc-ion batteries

“…Besides, electrolyte modulation is considered as a facile approach to stabilize metal anode by regulating the interface chemistry. [31][32][33][34][35] Recently, highly concentrated electrolyte (e.g., 1 m Zn(TFSI) 2 + 20 m LiTFSI (m: mol kg -1 ) 36 ) and deep eutectic electrolyte (e.g., ~4.2 m Zn(TFSI) 2 in nonaqueous acetamide 37 ) were proposed to form an anion-derived solid electrolyte interphase (SEI) layer on Zn anode. This SEI allows rapid Zn 2+ diffusion while blocks solvents and electrons, thus suppressing water-induced side reactions.…”

Non-concentrated aqueous electrolytes with organic solvent additives for stable zinc batteries

“…In addition, Figure 4c shows a magnified part of the GCD curve, C@Zn cells have extremely low polarization (47 mV), which is much lower than that of Zn cells (246.7 mV), and the different voltage hysteresis between the two anodes proves that C@Zn has a lower zinc nucleation barrier than zinc foil. [ 61,62 ] Under high current densities of 1 mA cm −2 (Figure 4d) and 5 mA cm −2 (Figure S4, Supporting Information), the Zn−Zn battery does not maintain a stable cycle and quickly breaks down because of a short circuit. In sharp contrast, C@Zn−C@Zn batteries are charged and discharged stably for up to 220 h, and the voltage hysteresis remains almost unchanged (Figure 4e).…”

Uniform Zn Deposition Achieved by Conductive Carbon Additive for Zn Anode in Zinc‐Ion Hybrid Supercapacitors