Download PDF
Review  |  Open Access  |  5 May 2024

High-energy and durable aqueous Zn batteries enabled by multi-electron transfer reactions

Views: 266 |  Downloads: 28 |  Cited:   0
Energy Mater 2024;4:400040.
10.20517/energymater.2024.12 |  © The Author(s) 2024.
Author Information
Article Notes
Cite This Article


Aqueous Zn batteries (AZBs) have emerged as a highly promising technology for large-scale energy storage systems due to their eco-friendly, safe, and cost-effective characteristics. The current requirements for high-energy AZBs attract extensive attention to reasonably designed cathode materials with multi-electron transfer mechanisms. This review systematically overviews the development and challenges of typical cathode hosts capable of multiple electron transfer reactions for high-performance Zn batteries. Moreover, we also summarize how to trigger the multi-electron transfer chemistry of cathodes, including transition metal oxides, halogens, and organics, to further boost the energy storage capability of AZBs. Finally, perspectives on critical issues and future directions of the multi-electron transfer battery systems offer novel insights for advanced Zn batteries.


Aqueous Zn battery, multi-electron transfer mechanism, cathode materials, high performance


As the global energy crisis in traditional fossil fuel energy continues, there is a growing urgency for developing clean and renewable energy sources, including wind, solar, hydrogen energy, and geothermal energy, towards achieving the goal of carbon peak and carbon neutrality. However, these clean energy sources are characterized by their intermittent nature, indirectness in conversion processes, and inherent instability, resulting in low energy utilization efficiency and high operational costs[1,2]. Therefore, aqueous batteries with low cost and safety play a pivotal role in efficient energy conversion and storage for large-scale energy storage[3,4]. Compared to lithium-ion and other polyvalent metal batteries, aqueous zinc (Zn) batteries (AZBs) have been regarded as promising systems due to their highly abundant Zn reserves, outstanding theoretical specific capacity (820 mAh g-1), and lower redox potential of -0.76 V versus standard hydrogen electrode (SHE)[5]. Figure 1A clearly represents the number of publications related to zinc-ion and aqueous Zinc-ion battery technology research, proving the great potential for AZBs in large-scale energy storage systems[6-24]. However, the current state-of-the-art Zn batteries are still limited by the challenges related to the serve side reactions including shape change, passivation, and hydrogen evolution reaction (HER) of Zn anodes, particularly in alkaline environments[25]. Therefore, adopting mildly acidic and neutral electrolytes has driven great progress in rechargeable AZBs such as Zn-MnO2 and Zn-V2O5 cells[26,27]. It is worth noting that the energy density and battery lifespan of AZBs are highly related to the electrochemical performance of cathode materials. Generally, the single-electron transfer mechanism typically results in inferior capacity and sluggish redox kinetics between electrodes for non-durable Zn batteries[28-30]. Hence, the rational design of cathode materials based on multi-electron transformation reactions is essential for advanced AZBs.

High-energy and durable aqueous Zn batteries enabled by multi-electron transfer reactions

Figure 1. (A) The number of publications related to zinc-ion battery and aqueous zinc-ion battery technology research. (B) Recently published cathode materials with improved capacity and cycling stability for high-performance AZBs, including Mn-[6-10], V-[11-14], and halogen-based materials[15-19] and organic hosts[20-24].

Besides Zn anode protection and electrolyte optimization, numerous strategies have been adopted to achieve high-performance cathode materials, including manganese (Mn)-based oxides, vanadium (V)-based oxides, Prussian blue analogs, organic compounds, and halogens[4,31,32]. Figure 1B displays the recent progress of modified cathode materials, suggesting that the electron transfer numbers can significantly enhance the capacity and stability in aqueous Zn devices. Specifically, the MnO2 cathode with MnO2/Mn3+ displays an energy density of ~280 Wh kg-1 based on MnO2 mass. Furthermore, the redox reaction of MnO2/Mn2+ endows decoupled Zn-MnO2 batteries with an ultra-high platform (~2.3 V) and excellent energy density of ~1,100 Wh kg-1[33]. Moreover, vanadium oxide (VO) cathodes with polyvalent states and relatively low molar mass generally undergo two-electron redox reactions and exhibit exceptional theoretical capacities over 600 mAh g-1 for advanced AZBs with ~450 Wh kg-1[34]. Furthermore, the calix[4]quinone (C4Q) cathode containing eight carbonyls exhibits an excellent energy density of 335 Wh kg-1 and a long lifespan over 1,000 cycles at 500 mA g-1. Recently, halogens involving multi-electron conversion chemistry have been proven promising conversion cathodes for high-performance AZBs[35]. For example, Chen et al. reported a four-electron transfer aqueous Zn-I2 batteries by triggering the redox reaction of I2/I+ by forming ICl inter-halogens, improving the energy density and battery lifespan to 495 Wh kg-1 and 6,000 cycles, respectively[36]. Conversely, cathode materials with substantial structural frameworks, such as covalent-organic frameworks, and polyanionic cathodes generally offer lower capacity (< 200 mAh g-1) and inferior redox potential (< 1.0 V) for unsatisfied Zn batteries. Despite the substantial advancements achieved thus far, achieving industrial-scale production remains a distant objective for AZBs to exceed the target of lithium batteries of 400 Wh kg-1 in the "Made in China 2025" project[36,37]. To enhance the Zn battery performance and overcome the challenges mentioned above, multi-electron transfer reactions have been considered a suitable alternative to single-electron transfer[38-40]. Therefore, it remains crucial to explore methods for achieving reversible multi-electron transfer reactions with enhanced output voltage, high energy density, and low cost-effectiveness in advancing the application of AZBs[40,41].

Despite their potential for high energy density and commercial viability, we should further explore the multiple electron-transfer chemistry of cathode materials matched with the addition of redox couples in electrolytes, especially in mild acid or natural electrolytes. In order to attain stable long-term cycling and achieve high-rate performance, improvements in ion transport and storage capability are imperative for the metal oxide cathodes with sluggish ion insertion kinetics[42]. The key to realizing cathode materials with remarkable energy density lies in optimizing crystal or molecular structures while activating reversible multi-electron reactions, which requires continuous exploration and discovery of novel chemical systems. Additionally, attention must be paid to balancing the cathode output energy density with excellent cycling stability. Hence, understanding the intrinsic structure-effect relationship among the battery performance indexes is critical for designing high-energy AZBs with long lifespans[42,43]. This review aims to capture the challenges and the latest developments posed by cathode materials based on multi-electron transfer mechanisms in reported AZBs. Furthermore, we explore potential solutions to effectively trigger the multiple-electron transfer reactions for enhanced cathode materials. The ultimate goal is to offer valuable insights that can be utilized to develop better AZBs for the future energy world.


Cathode materials undergo multi-electron chemical reactions triggered by the migration of electrons from the Zn anodes during the discharge process. This reaction involves converting the cathode material into different chemical forms or variations in chemical valence, which stores the energy until it is needed during the charge process. Mn-based, V-based compounds, halogen, and organic hosts are common cathode materials based on multi-electron transfer reactions for high-energy AZBs. However, activating more than single-electron transfer chemistry in these materials requires different excitation pathways. For example, the MnO2/Mn2+ mechanism in Mn-based compounds can be divided into three excitation categories, including the dissolution-deposition reaction of MnO2 cathodes, chemical environment optimization of cathode/electrolyte interface (CEI), and pre-deposition surface to active MnO2/Mn2+ reaction. Due to the ultra-high theoretical capacity of V-based compounds with V5+/V3+ reactions, it is extremely important to limit the dissolution of active substances, the generation of byproducts, and the slow diffusion kinetics to enhance the reaction activity of Zn-V batteries. Therefore, the modification strategy for more than two-electron transfer of stable V-based cathode hosts can be divided into the material design and the electrolyte modification.

Compared to the previous two types of cathodes, the number of electrons transferred in halogen (chlorine, bromine, and iodine) cathode materials is still being determined, and the conversion mechanism exploration is urgent for constructing advanced Zn-halogen devices. For example, the maximum electron transfer from I- to IO3- can reach the twelve-electron transfer reaction for high-energy Zn-I2 batteries. Yet, the modification strategies are essential to ensure the realization of a multi-electron transfer mechanism with a long lifespan. Besides the halogen cathodes, it is worth noting that a multi-electron chemical reaction can be initiated in organic hosts containing multiple redox centers by optimizing molecular structures to achieve high-energy and durable Zn-organic batteries. The battery energy is determined by $$ E_{g}=-\frac{n F E}{\Sigma M g} \eta $$, where ΣMg is the total weight of reactants (mol g-1), n represents the charge transfer number, E is the voltage (V), F is the Faraday constant, and η means the activity of charge carriers, including both cations and anions that participate during the redox (multi-ion effect)[44]. Thus, the strategies for higher battery energy can be achieved by enhancing the voltage, multi-electron reaction transfer number, and mass ration of light elements in electrode materials.

The following sections are an overview of the recent development and issues of reported cathode materials. Furthermore, the corresponding strategies are provided to enhance the capability of accept/donate multiple electrons during the battery working, thereby boosting the battery practical application of high-performance AZBs.

Mn-based cathodes with MnO2/Mn2+ mechanism

The variable valence states of Mn atoms and diverse crystal structures of manganese oxides enhance their suitability as an exceedingly captivating cathode material for high-performance AZBs[45,46]. The two-electron transfer reaction of MnO2/Mn2+ endows Mn-based cathode materials with a notable theoretical specific capacity (616 mAh g-1) and an ultra-high redox voltage (~1.9 V) in acid electrolytes. Besides, electrolytic Zn-MnO2 batteries significantly boost the voltage and capacity based on the dissolution-deposition reaction of MnO2/Mn2+, surpassing the energy limitation of the MnO2/Mn3+ reaction. For example, Chao et al. proposed an electrolysis Zn-MnO2 battery via proton and electron dynamics for achieving high energy of 409 Wh kg-1 with a competitive battery cost of ~US$5 per kWh[46]. However, the strong acid H2SO4 as the electrolyte addition causes inferior cycling stability in electrolysis Zn-MnO2 batteries. Therefore, we focus on developing and modifying strategies to active MnO2/Mn3+/Mn2+ reactions in the mild acid environment, highlighting the modification methods of the dissolution-deposition reaction, chemical environment near the CEI, and the tailored electrodeposition surface for triggering MnO2/Mn2+ reaction [Figure 2].

High-energy and durable aqueous Zn batteries enabled by multi-electron transfer reactions

Figure 2. Schematic illustration of three ways to stimulate the dissolution/deposition reaction of MnO2/Mn2+ for high-performance Zn-Mn batteries.

Dissolution-deposition reactions of MnO2 cathodes

Since 2016, significant advancements have been made in understanding the mechanisms of Zn-Mn batteries. Pan et al. discovered that adding MnSO4 to the mild acid ZnSO4 electrolyte can effectively suppress the dissolution of MnO2[47,48]. In 2018, Fu et al. demonstrated that Mn2+ convert into Mn(III)-based oxides could contribute additional capacity, surpassing the theoretical capacity limit of 308 mAh g-1 based on MnO2/Mn3+ reaction[49]. This finding underlined the importance of the two-electron transfer between Mn2+ and MnO2, thereby attracting the widespread interest of researchers. Further reports by Xie et al. in 2019 demonstrated the electrodeposition mechanism of Mn2+ from the electrolyte to form MnO2, boosting the capacity and cycling stability of electrolysis Zn-Mn batteries[48]. These insights suggest that efficient design of Mn-based oxide materials can trigger the reversible dissolution-deposition reaction of MnO2/Mn2+ in the mild acid environment, facilitating the development of high-energy Zn-Mn batteries.

Henceforth, Xia et al. enhanced δ-MnO2 capacity and stability by incorporating high-valence Mo5+ ions, altering the Mn-O bond angle and inducing structural distortion (Jahn-Teller effect) in the [MnO6] octahedron of Mo-ZnMn2O4[6]. This modification promoted the dissolution of Mn(III)-based oxides into the electrolyte and enabled the activation of the MnO2/Mn3+/Mn2+ reaction, doubling the specific capacity to 652 mAh g-1 at 0.2 A g-1[6]. Furthermore, the Co-doped δ-MnO2 catalyzes the electrochemical deposition of active Mn compounds, enhancing self-recovery and energy storage performance of Zn-Mn batteries[7]. Besides ion doping strategies, constructing Mn-based hybrid hosts also greatly facilitates two-electron transfer reactions for high-energy AZBs. For example, the MnO2/MoO3 hybrid cathode with the reversible double electron transfer reaction exhibits a high capacity of 333 mAh g-1 caused by the weakened energy barrier for Mn2+ release and stronger attraction to Mn2+ during battery cycling tests in an electrolyte without Mn2+ additives[8]. Furthermore, Radha et al. prepared carbon-coated MnOx cathodes to achieve the reversible Mn4+/Mn2+ redox chemistry for advanced Zn-Mn batteries[50]. Specifically, birnessite-type MnO2 was in-situ generated utilizing electrolyte addition of Mn2+ and finely divided MnOx particles during the charging process[50]. It is worth noting that the conductive carbon substrate further provides active sites for the MnOx cathode, yielding a peak energy density of 845.1 Wh·kgcathode-1 with an extended cycle life of 1,500 cycles[51].

In the reduction process of solid MnO2 to Mn2+, the absence of active sites for capturing dissolved Mn2+ can lead to significant capacity decline during battery cycling. To address this, strategies such as employing a carbon coating for surface protection and incorporating a porous carbon interlayer have been proven to substantially improve the electrochemical performance of Zn-MnO2 batteries by capturing dissolved Mn2+ ions[52]. Ultimately, the primary challenges in the dissolution-deposition energy storage mechanism of Mn-based cathode materials are severe capacity degradation and poor cycling stability. Therefore, it is essential to optimize Mn-based cathode materials, enhancing the Mn3+/Mn2+ conversion efficiency and ensuring the structural integrity for high-energy and stable Zn-Mn batteries.

The chemical environment adjustment near the CEI

Studies have identified the root causes of capacity degradation in Zn-Mn batteries based on the MnO2/Mn2+ reaction during cycling. As a result, the increased pH value and Mn3+ concentration in the electrolyte and the accumulation of inactive MnO2 (designed as “dead MnO2”) near the CEI severely hinder ion diffusion and reaction efficiency of MnO2/Mn2+[53-56]. Therefore, efforts are currently focused on preventing the disproportionation of Mn3+, eliminating “dead MnO2”, and enhancing the applications for Zn-Mn batteries[15]. To address these issues, strategies such as increasing proton concentration, introducing ligand ions such as F- or P2O73-, and employing innovative electrolytes have been explored[57]. Xie et al. used Mn(AC)2 rather than conventional MnSO4 electrolytes to boost the direct conversion of Mn2+ to MnO2, resulting in a lower initial oxidation potential for fast-charging Zn-MnO2 devices in the Mn(Ac)2 system[48]. More importantly, incorporating redox couples such as Cr3+/Cr2+ or Fe3+/Fe2+ in acetate-based electrolytes further endows electrode functionality by removing inert species and optimizing cathodic potential, thereby improving the energy density and battery life[58,59]. In-situ electrochemical quartz crystal microbalance (EQCM) techniques provide insights into the deposition/dissolution chemistry of MnO2 cathodes, promoting the development of high-performance AZBs[59]. Very recently, iodide (I-) as a catalyst addition can boost the reduction of solid MnO2 to Mn2+, optimizing electrolysis kinetics and conversion efficiency[60,61]. More importantly, the effective removal of “dead MnO2” also temporarily reduces capacity attenuation and increases the cycle life, contributing to the industrialization of high-energy Zn-Mn batteries.

Electrodeposition surface to active MnO2/Mn2+ reaction

Very recently, the cathode-free Zn-MnO2 battery system has demonstrated the deposition/dissolution reaction of MnO2/Mn2+ on the cathode side for the higher energy density[45]. This system, characterized by a high redox potential (~1.99 V vs. Zn/Zn2+), benefits from carbon felt on the cathode side, providing active sites for efficient deposition of MnO2 and reduced capacity decay caused by Mn2+ dissolution[46,62-64]. These findings offer fresh insights into the operation of Zn-MnO2 batteries, especially in stationary applications, where the energy storage mechanism remains complex due to pH fluctuations and the formation of intermediate products during charge-discharge cycles[65-67]. In-depth studies using diverse in-situ detection techniques reveal that weakly acidic sulfate electrolytes can induce subtle changes in pH values, forming byproducts such as Zn4SO4·(OH)6·xH2O (ZSH)[68-70]. These byproducts are essential in the dissolution-deposition reaction and provide insights into the MnO2/Mn2+ redox processes with non-MnO2 cathode materials. In electrolytes containing Mn2+, ZSH actively participates in the electrochemical reaction and forms layered zinc vernadite (ZnxMnO(OH)2) nanosheets on the cathode side. During the discharge process, these ZnxMnO(OH)2 nanosheets react with proton ions to alter the surface pH and promote ZSH re-deposition. This process enhances the dissolution-deposition reaction of Mn2+/ZnxMnO(OH)2 catalyzed by ZSH, which is crucial for enhancing cycle stability and better battery performance of Zn-Mn batteries[71].

In a weakly acidic electrolyte environment of zinc sulfate, ZnO, MgO, CaO, etc., can further be used as cathode catalytic materials to activate the two-electron transfer reaction in electrolytic Zn-Mn devices. However, these catalytic substrates with varying performances exhibit distinct properties in inducing the deposition mechanism for Zn batteries. For example, the Zn-CaO battery shows remarkable capacity retention compared to the Zn/MgO battery, possibly due to the stable CaSO4·2H2O phase deposition on the CaO cathode[72]. This study contributes to a better understanding of Zn-Mn batteries and guides the design of high-capacity ones in mild acid environments.

Long-cycle Zn-Mn batteries with stable and high capacity are required for their commercialization in large-scale energy storage applications. Based on the above three excitation methods of two-electron transfer of Mn-based oxide materials, the introduction of defects in Mn-based dioxide, the electrolyte addition of redox couple, and substrate design for catalytic deposition of active Mn-based oxides are promising excitation methods for high-performance Zn-Mn batteries with the two-electron mechanism of MnO2/Mn2+ for high-energy and durable Zn-Mn batteries.

Vanadium-based cathodes with the V5+/V3+ reaction

V-based oxides are another promising cathode material due to their low cost, high theoretical specific capacity (+3 $$\rightleftharpoons$$ +5 for V2O5, 589 mAh g-1)[73,74], and reversible cycling stability[75]. However, the practical application of Zn-V batteries faces great challenges of inferior cycling stability, low capacity, and poor rate capability caused by the dissolution of active substances, poor conductivity, and sluggish Zn2+ diffusion kinetics. Therefore, enhancing the redox activity of V-based cathode materials is essential for high-rate and high-energy AZBs. Based on these, this section summarizes the ways to solve the above issues, including modifying V-based materials and the electrolyte optimization strategy [Figure 3].

High-energy and durable aqueous Zn batteries enabled by multi-electron transfer reactions

Figure 3. Graphic depiction of challenges and design strategies for constructing high-performance vanadium-based cathodes with more than two-electron transfer mechanism.

Improved V5+/V3+ reaction activity

One common issue with V-based cathode materials is the serve capacity fading caused by the low conductivity and active material dissolution during the battery cycling test. Incorporating conductive materials such as MXene (the family of two-dimensional transition metal carbides), nitrides, and carbonitrides[76,77], graphene oxide (GO)[78], reduced GO (rGO)[79-82], and carbon nanotubes (CNTs)[83] into V-based composite cathode materials significantly enhances redox activity with the restrained vanadium dissolution and byproduct formation. Besides, carbon-based materials also act as conductive additives into V-based hosts via merely physical mixing with active substances. Such direct compositing with V-based materials can significantly enhance the conductivity and stability for the improved energy density of Zn-V devices. The dissolution of vanadium and formation of byproducts can be effectively inhibited by coating carbon materials onto the surface of V-based cathodes. Wan et al. developed a KV3O8·0.75H2O (KVO) material coated with single-walled CNTs (SWCNTs) to obtain an independent KVO/SWCNTs cathode film, which displayed high capacity (379 mAh g-1 at 0.1 A g-1), excellent rate performance (92 mAh g-1 at 5 A g-1), and remarkable capacity retention rate of 91% over 10,000 cycles[11]. Therefore, introducing conductive carbon materials is effective for the enhanced reaction activity of V-based hosts in high-performance Zn batteries.

V-based cathodes often exhibit layered and tunneling characteristics, limiting the Zn2+ diffusion kinetics caused by the electronegative O atoms[84]. Hence, ion doping and organic intercalation as the modified strategies have been explored to enhance the rate capability and stability of Zn-V batteries[85,86]. For instance, free-standing Ca-doped V2O5 (a-Ca-V2O5) with high utilization of the abundant active sites exhibits fast reaction kinetics and improved discharge capacity even at large current densities[12]. Density functional calculations (DFT) revealed that doped Ca atoms yielded lower adsorption energy for inserted Zn2+ ions, thereby facilitating rapid reaction kinetics and achieving exceptional rate performance during the Zn2+ insertion/extraction process. Besides ion doping, Song et al. utilized p-aminophenol (pAP) pre-intercalated into layered V-based oxides of V3O7·H2O, increasing the V-O layer spacing to improve rate performance and cycle life[13]. The pAP intercalated-V3O7·H2O hybrid cathode exhibits double electron transfer, demonstrating remarkable reversible specific capacity (386.7 mAh g-1 at 0.1 A g-1) at the high mass loading of 6.5 mg cm-2[13]. Recently, Ma et al. successfully developed an organic-inorganic hybrid cathode by combining the high capacity of VO with the high working voltage of ethylenediamine (EDA), resulting in a remarkable working voltage of up to 0.82 V and ultra-long lifespan of VO-EDA cathodes[87]. Furthermore, the incorporation of EDA molecules also improved ion diffusion ability, achieving higher capacity (382.6 mAh g-1 at 0.5 A g-1) and extended cycle life (10,000 cycles)[87]. Therefore, the intercalation modification strategies offer insights for exploring high-energy V-based cathode materials. Furthermore, intercalating ions such as K+, Na+, Cs+, Li+, and Zn2+ can also significantly improve the structural stability and cycling performance of Zn-V devices[86,88-91]. For instance, Wang et al. reported a novel cathode of Mg2+ pre-intercalated V-based oxide (designed as MgV2O6·1.7H2O), enhancing the V-O layer distance for high redox kinetics and cathode integrity[92]. These above-mentioned modification strategies for cathodes have significantly enhanced the capacity, discharge platform, and rate performance of VO cathodes, thereby constructing advanced Zn-V systems for practical applications.

Improved CEI and additional redox couples

Optimizing the electrolyte is another critical strategy for developing high-performance Zn-V batteries. V-based cathodes generally suffer from the dissolution of V elements and irreversible structure collapses in conventional aqueous electrolytes, such as ZnSO4 and Zn(CF3SO3)2. In light of this, the formation of CEI on the cathode surface prevents the side reactions and harmful substance exchange between the V-based cathode and the electrolyte, such as interlayer water shuttling effect and V-based compound dissolution. Among various options, using high concentration electrolytes enhances the cycling stability of the V-based cathodes. However, it still faces the challenges of water molecular interaction and the inferior rate capability of V-based cathodes during battery cycling. Hence, forming a reliable and stable CEI is crucial for zinc-vanadium batteries with high energy density, particularly during the long cycling test. To lower the cost of the high concentration electrolyte, Wang et al. introduced an ultra-low water activity electrolyte addition of trimethyl phosphate (TMP) to improve the stability and capacity of Zn-V6O13 batteries, significantly suppressing vanadium dissolution and side reactions at the cathode interface[14]. Therefore, the Zn-V6O13 battery with the innovative electrolyte addition exhibits an exceptional cycle life of up to 30,000. In light of these findings, the electrolyte modification strategy not only provides a more stable CEI interface but also inhibits vanadium dissolution to minimize byproduct deposition.

Additionally, functional electrolyte additives, such as I2/I-, can provide additional discharge capacity by participating in the energy storage process. Considering the higher redox potential of I2/I- than that of V5+/V3+, many researchers have attracted much attention to this modification strategy to construct high-energy Zn-V batteries. Recently, Yang et al. proposed an ethylene glycol solution of Zn(CF3SO3)2 and ZnI2 for a dual-functional cathode of NH4V4O10 and porous active carbon (AC) to realize the synergistic effect of Zn2+ insertion/extraction and electrolyte-assisted I2/I- conversion reaction mechanism[93]. During the cycles, three-electron transfers (one-electron transfer for halogen ion) were realized, which obtained higher discharge medium voltage (0.96 V) and capacity retention rate (0.032%/cycle) at 0.2 A g-1[93]. The unique electrolyte modification method has deeply explored the compatibility of halogen redox and Zn2+ insertion/extraction, improving the cycle stability and energy density of aqueous Zn-V batteries. Therefore, improving the redox activity of V5+/V3+ chemistry along with additional redox couples is the future developing direction for high-energy and long-life Zn-V batteries.

Halogen-based cathodes with multi-electron transfer chemistry

In contrast to conventional Zn batteries based on the ion insertion/extraction mechanism, Zn-halogen batteries (Zn-X2, X=Cl, Br, and I) exhibit a distinct energy storage chemistry through the conversion reaction between halogen and their ions. The conversion mechanism of halogen cathodes can avoid the issues of lattice distortion, sluggish Zn2+ diffusion, and poor conductivity in V- and Mn-based cathodes. Besides, the rich valence states of halogen atoms can achieve multi-electron transfer under certain conditions, thereby constructing long-life and high-energy AZBs [Figure 4][94,95]. When halogen hosts directly act as the cathodes, conductive and porous carbon materials are generally utilized as stabilizers to fix the halogen atoms, which is highly related to the electrochemical performance and lifespan of the Zn-halogen batteries[96]. Yet, the mass loading of the halogen host is limited by the conductive carbon-based additions, resulting in inferior areal capacity and rate capability for the AZBs.

High-energy and durable aqueous Zn batteries enabled by multi-electron transfer reactions

Figure 4. Schematic illustration of the energy storage mechanisms, issues, and modified strategies for Zn-X2 batteries (X = Cl, Br, I, n = 1, 3, 5).

In the case of the conversion energy storage mechanism, it is also possible to prepare a cathode-free battery system by introducing halogen ions into the electrolyte, such as the electrolytic Zn-chlorine[97], Zn-bromine[98], and Zn-iodine electrodes[99]. Moreover, Zn-halogen devices are cost-effective compared to other cathode materials due to the abundance of halogen elements in the ocean. The multiple valence states of halogen elements (-1, 0, +1, +3, +5, and +7) make halogen hosts highly promising for high-energy AZBs. The reversible conversion reaction based on X2/2X- involves a two-electron transfer chemistry, leading to the harmful polyhalides through the reactions between X2 and X-. Furthermore, it is interesting to note that three, four or even six-electron transfer reactions can also be triggered under the influence of other halogen ions in the electrolyte, thereby achieving the ultra-high energy density of 200 Wh kg-1[17,100]. Therefore, high-energy and low-cost Zn-halogen devices exhibit application prospects to replace commercial lead-acid batteries with strong acid electrolytes and heavy metal lead pollution[101,102]. The early-stage challenges of Zn-halogen batteries primarily include polyhalides shuttling effect and low energy conversion efficiency, leading to serious Zn corrosion, slow reaction kinetics, and poor lifespan. The following section mainly focuses on constructing high-performance Zn-halogen batteries through the modified methods of optimizing cathode material structures, incorporating functional electrolytes, and adjusting separator types.

Cl-based batteries with multi-electron transfer reactions

The chloride redox reaction (ClRR) in Cl-based batteries, known for its cost-effectiveness, high redox potential of 1.36 V (vs. SHE), and excellent theoretical capacity (756 mAh g-1 for two-electron Cl-based reaction), has gained prominence for producing high-energy AZBs[103,104]. However, the gas-liquid two-phase conversion reaction of ClRR faces the challenges of redox irreversibility and inferior cycling stability caused by the inadequate fixation of chlorine and electrolyte decomposition. These issues significantly influence the practicality of Zn-Cl2 batteries[97,105]. Enhancing chlorine fixation is vital for developing effective Cl-based devices, especially for the activation of multi-electron transfer chemistry. Recent efforts have focused on immobilizing oxidized chlorine in carbon-based host materials, including AC, graphite, CNTs, and porous carbon spheres[16,106]. Wang et al. developed a graphite cathode for accommodating the electrochemical generation of bromine and chlorine, demonstrating an increased average discharge voltage of 1.71 V and a capacity reaching up to 257 mAh g-1 based on double halogen redox reactions involving two-electron transfers (Br0/Br- and Cl0/Cl-)[18]. However, physical adsorption on carbon-based materials cannot fully prevent Cl2 precipitation, Cl3- dissolution, and Cl2 decomposition reaction, affecting the coulometric efficiency and cycling stability of Cl-based batteries[107].

Compared to carbon materials, a cathode that can form stable chemical adsorption via the chemical bonds with chloride species is required for reversible ClRR. A novel approach by Chen et al. involved diphenyl diselenide (di-Ph-Se) as a cathode material to activate the Se-halogen synergistic chemistry for efficient chlorine fixation[17]. This resulted in a highly reversible ClRR with low Cl2 emission and a significantly elevated discharge voltage (1.87 V vs. Zn2+/Zn). Each Ph-Se in the cathode can facilitate the fixation of two oxidized Cl0 and enable the polyvalent conversion of Se, thereby triggering a six-electron transfer reaction for an ultra-high energy density of 665 Wh Kg-1 with a high average voltage and coulombic efficiency (CE) of 1.51 V and 99.3%, respectively. Furthermore, the packaged Zn//Ph-Se/Cl exhibits a notable area capacity of 6.87 mAh cm-2 and exceptional self-discharge performance, demonstrating the practical application potential. The chemical reaction of Se and Cl synergism provides a novel approach for achieving reversible and efficient halogen redox reactions.

In addition to the rational design of cathode materials for achieving effective adsorption of chloride species, employing the redox reaction of active substances in the electrolyte represents a novel strategy for promoted Cl fixation. Similarly, the catalytic effect of metal ions is also evident in Zn-Cl2 batteries. Chen et al. introduced trace amounts of Mn2+ ions into the electrolyte, forming an in situ MnO2 redox adsorbent to aid in Cl2 adsorption during the charging process[108]. The resulting Zn-Cl2@MnO2 battery based on a multi-electron transfer mechanism exhibits a high voltage of 2.0 V at 2.5 mA cm-2 and exceptional cycling stability over 1,000 cycles with an average CE of 91.6%[108]. These above-mentioned approaches present a promising direction for advancing viable aqueous Cl-based batteries.

Br-based batteries with multi-electron transfer reactions

Compared to Cl-based batteries, Zn-bromine (Br2) batteries with lower volatility and toxicity have seen practical advancements, including commercial demonstrations at the kW/kW h-1 level[109]. In 1980, the Zn-Br2 battery introduced by Eustace et al. was a groundbreaking milestone, offering a high voltage of 1.85 V, a theoretical capacity of 335 mAh gBr-1, and a theoretical energy density of 440 Wh kg-1[110,111]. However, challenges of the corrosiveness of Br2 and the diffusion of soluble polybromine anions (Br3-, Br5-, etc.) can cause Zn anode corrosion and low CE, preventing further progress in Zn-Br2 systems[112-115].

Early single-chamber Zn-Br2 batteries utilized high-density Br2 and low water absorption for physical separation, offering a cost-effective storage solution. Yet, this system still faces the volatilization of Br2 gas[102]. To address this issue, electrode materials, particularly conventional carbon materials such as porous carbon, are used for their conductivity, large surface area, and stability. They provide active sites for bromine ion adsorption but require enhanced catalysis and Br storage capacity[116-119]. Building upon this foundation, Xiang et al. utilized N-doped carbon materials as adsorbents to enhance the capacity with high reversibility, although some Br species still escaped[116]. Wang et al. designed a novel cage-like porous carbon material (CPC) with tailored pore sizes according to the molecular size of Br- ions and bromine complexes (MEP+ and MEPBR3)[18]. The optimized CPC can successfully fix Br2 within their porous structures, effectively preventing Br2 gas leakage for stable Br-based cathodes over 300 cycles[18]. With advancements in anode, cathode, and electrolyte modifications, zinc-bromine batteries with multi-electron transfer capability and high discharge voltage are now commercially viable. Continuing research focuses on enhancing CE and energy efficiency for further improvements.

Xu et al. constructed a practical water-based Zn-Br2 static battery based on continuous Br-/Br0/Br+ redox reactions, which solved the shuttle and hydrolysis problems of polybromides (Br3- and BrCl2-) by synergizing pyridine complexation chemistry and the salting-out effect of ZnSO4 water-based electrolyte[120]. Pyridinium-polybromide complexes (HPY Br) can be used both as a complexing agent and active material and show excellent binding strength with polybromides. Additionally, 3 M ZnSO4 causes a strong salting-out effect through SO42-, which is beneficial to the dissociation of complexes. Benefiting from these advantages, the two-electron Zn-Br static battery exhibited good cycling stability (88.5% retention after 1,000 cycles), a high CE of 99.8%, and an energy efficiency of 89.9%[120]. This type of Zn-Br2 battery shows great potential for expanded applications, and its cost in production is expected to be quite cheap. It provides a promising sustainable power source of high-performance and low-cost Zn-Br2 batteries for large-scale energy storage.

I-based batteries with multi-electron transfer reactions

Iodine (I2) stands out among halogen batteries for its low toxicity and corrosion, plus the practicality of solid I2 for large-scale energy storage, making it one of the fastest-developing Zn-halogen batteries based on the I2/2I- chemistry[109]. However, challenges such as the polyiodide shuttle effect, Zn corrosion, and low CE severely limit the development of Zn-I2 devices[121]. Recent advancements in pinning I2 hosts have focused on porous carbon materials[122,123], single-atom metal-nitrogen carbon materials[124], metal complexes[125], and conductive polymers[126]. The shuttle problem of polyiodide ions can be fundamentally solved by improving the reaction kinetics and reducing the production of polyiodide ions[127]. Zhang et al. developed a starch-iodine complex as the cathode material to limit the polyiodide shuttle effect, enhancing the lifespan of up to 50,000 cycles in the modified Zn-I2 battery[19]. Additionally, novel electrolytes and functionalized membranes are crucial in effectively preventing the polyiodide shuttle during battery working[128-130]. For instance, Chen et al. designed a vermiculite nanosheet (VS) suspension electrolyte, which can efficiently anchor polyiodides and improve the cycling stability[131]. This study demonstrated that the Si-O bond between the primary intermediate I5- and VS possesses high binding energy, enabling efficient anchoring of dissolved polyiodides on the VS surface[131].

To achieve high specific energy Zn-I2 batteries, the characteristics of iodine elements with variable valence states are utilized to stimulate new redox couples with enhanced electron transfer numbers and higher reaction potential. Zou et al. introduced an aqueous zinc-iodine battery with a four-electron transfer, leveraging the redox couple of I+/I2 (1.83 V vs. Zn2+/Zn) and I2/I- (1.29 V vs. Zn2+/Zn) with ZnCl2 electrolyte. This approach resulted in an increased specific capacity of 594 mAh g1 and an energy density of 750 Wh kg-1 over 6,000 cycles[15]. Earlier attempts to use iodine oxides of IO4-/IO3- in an acidic electrolyte for multi-electron transfer face issues such as HER and Zn corrosion[132-134]. A recent breakthrough with a six-electron transfer redox couple of IO3-/I- achieved impressive capacities of 1,200 mAh g-1 and energy densities of 1,357 Wh kg-1 by employing halogen interchange chemistry with Br-[100]. This cycling process happened through halogen interchange chemistry between I2 (in the electrode) and Br- (in the acidic electrolyte). Specifically, the polar IBr halogen interchange intermediate formed undergoes nucleophilic reaction with H2O to form IO3- during the charging process. During discharge, Br- acts as a catalyst for the dissociation of IO3- and reduces it to IBr and Br2. Therefore, iodine-based devices offer significant potential for high-energy and fast-charging Zn batteries with a long lifespan.

Based on previously mentioned Zn-halogen batteries with multiple electron transfer mechanisms, Zn-I2 devices have induced great attention for high-energy AZBs with the twelve-electron transfer reaction. However, the lighter molar mass of Br and Cl is positive for further improving the battery energy density. Therefore, preventing the gas formation of Cl2 and Br2 and the shuttle effect for the inferior CE and lifespan are urgent for developing high-performance Zn-halogen batteries.

Organic cathodes with multi-redox centers

Compared to inorganic cathode materials, organic cathodes with low mass, flexible molecular chains, and multiple redox groups generally offer improved structural stability, better rate performance, and the potential for higher energy densities[135-138]. Besides, the organic cathode in Zn batteries prevents Zn dendrite formation and extends battery life by creating a chemical barrier[139,140]. The energy storage mechanism in aqueous Zn-organic batteries (AZOBs) is driven by the insertion of Zn2+ or H+ ions combined with multiple active sites in the organic cathode materials during the discharge process[141-143]. As illustrated in Figure 5, electron transfer at the cathode often involves conjugated structures and delocalized electrons to facilitate ion and electron transfer kinetics[144-146]. Despite these advantages, organic cathodes face challenges such as low actual capacity, poor cycle stability, and inadequate rate performance, primarily due to low electronic conductivity and unstable organic intermediates[20,147]. Organic cathodes with redox-active centers such as C=O and C=N can improve electron transfer numbers by providing more reaction sites and faster electron transfer kinetics, increasing energy density and stability[140,148,149]. For example, quinone compounds and their derivatives including 6,8,15,17-tetraaza-heptacene-5,7,9,14,16,18-hexaone (TAHQ), 9,10-phenanthraquinone (PQ), tetracyanoquinodimethane (TCNQ), pyrene-4,5,9,10-tetraone (PTO), and 8,21-dihydronaphtho[2,3-a]naphtha[2',3':7,8]quinoxalino[2,3-i]phenazine-5,11,16,22-tetraone (DADB) exhibit multi-functional groups for boosting multiple electron transfer reactions for achieving advanced AZOBs[143,148-150]. Therefore, the rational design of organic molecular structures is the primary method for boosting their battery performance.

High-energy and durable aqueous Zn batteries enabled by multi-electron transfer reactions

Figure 5. Diagrammatic representation of the energy storage mechanism, challenges, and structural modification strategies for high-performance Zn-organic batteries with multiple electron transfer reactions.

The selection of organic cathode materials for activating multi-electron transfer reactions is a complex decision involving a thorough evaluation of various factors to determine the optimal option for a specific application. The C=O (carbonyl) group is generally preferred over the C=N (imine) group due to its higher reduction potential, better stability, and stronger interaction with zinc ions, enhancing its electrochemical performance. However, some C=N and C≡N compounds have shown excellent electrochemical performance, depending on their specific molecular structures, electrolyte composition, and battery operating conditions[139,141,146,149,151-153]. To tackle the concerns mentioned above, it is imperative to modify the organic cathode structure to enable multi-electron transfer reactions for the enhanced battery performance. Recent strategies include modifying and rearranging the organic structures in various ways that further nudge the organic cathode to the subsequent multi-electron transfer[154-157]. The primary causes of the low conductivity of the organic cathodes are caused by the molecular structure of organic compounds with wide highest occupied molecular orbital-lowest unoccupied molecular orbital (HOMO-LUMO) energy gap values[158-161]. For instance, Zhao et al. fabricated a carbon-based poly(meta-aminophenol, 3-AP)/poly(para-aminophenol, 4-AP) hybrid cathode for four-electron transfer AZOBs with a high capacity of 347 mAh g-1 at 0.2 A g-1[21].

Addressing the high solubility and weak molecular bonding of organic cathodes requires increased active sites with high stability[21,152-154,162,163]. Peng et al. described the benzo[a]benzo[7,8]quinoxalino[2,3-i]phenazine-8,17-dione (BBQPH) cathode with reversible multi-electron transferred by the Zn2+/H+ co-insertion mechanism, exhibiting a superior capacity reservation of 380 mAh g-1 after 1,000 cycles at 5 A g-1 and an excellent energy density of 355 Wh Kg-1[39]. Challenges such as sluggish ion diffusion are addressed by improving the morphology and electrical conductivity of organic molecules in cathode materials. For example, Zhao et al. sequentially deposited poly(1,5-naphthalenediamine, NAPD) and poly(para-aminophenol, pAP) onto porous carbon to fabricate the C@multi-layer polymer cathode with an enhanced capacity of 348 mA h g-1 at 0.1 A g-1[164]. The intrinsic electrical conductivity in conjugated organic cathodes generally exhibits the rapid diffusion pathway of Zn2+ ions for improved rate capability of AZOBs[165-167]. By utilizing electroactive phenazine, Ye et al. prepared a liner π-conjugated poly(phenazine-alt-pyromellitic anhydride) (PPPA) cathode material with both C=O and C=N groups[22]. Quinone-based PPPA cathodes provide a remarkable capacity retention of 140 mAh g-1 and ultra-high lifespan over 20,000 cycles at 5 A g-1, evaluating promising applications in Zn//PPPA devices[22].

In addition to increased redox activity, introducing multiple redox elements of halogen, sulfide, and selenium has been drawing great attention to enhance electron transfer reactions of high-performance AZOBs[23,148,168-170]. For example, Chen et al. developed dual-ion Zn-triphenylphosphine selenide (Zn‖TP-Se) batteries with a high-potential triphenylphosphine selenide organic cathode, achieving excellent cycling performance and remarkable discharge capacity after 4,300 cycles with a flat discharge plateau at 1.96 V[170]. Attention to selenium-based cathodes is growing due to their potential for fast charging and improved long-term cycling performance[148,171-174]. Recently, Zhang et al. utilized polyaniline (PANI) as the catalytic cathode material to trigger the dual-redox mechanism of Zn2+ insertion and I-/I3-, thereby achieving a high areal capacity of ~1.0 mAh cm-2 after 200 cycles[175]. Therefore, evaluating and assessing multi-functional organic cathodes matched with multiple redox couples is essential for developing high-performance Zn-organic batteries. Covalent organic frameworks (COFs) have emerged as a promising approach for enhancing the electron transfer kinetics and redox potential of AZOBs. For example, the COF (Tp-PTO-COF) with numerous carbonyl active sites exhibits a high pair of redox peaks at 1.53 V/1.54 V caused by the anti-aromatic effect[44]. Moreover, a high capacity of 208 mAh g-1 and stable cycling over 1,000 cycles demonstrate the contribution of dual-redox sites (C=O and C=N) in the Tetraamino-p-benzoquinone- Benzoquinone (TAQ-BQ) COF cathode host[176,177].


AZBs with cost-effectiveness and intrinsic safety have emerged as promising candidates for the large-scale energy storage systems. However, several challenges impede their widespread adoption including limitations in the energy density and battery lifespan. This paper comprehensively reviews multi-electron transfer cathode designs, including Mn-based oxides, V-based oxides, halogens, and organic compounds. To further enhance the performance of zinc-based devices, it is imperative to explore new modifications and designs in cathode structures. The selection of the optimal cathode material is crucial for battery performance, necessitating a thorough evaluation of the specific requirements for different cathode hosts. Remarkable cathode materials significantly enhance the overall efficiency and energy density of the battery. The goal of current research in this area is to facilitate multiple redox reactions within a confined voltage range to achieve the high energy density and long lifespan. Pursuing alternative structural modification strategies for these common multi-electron transfer cathode materials is essential, such as metal oxide nanostructure doping agents, redox mediators (RMs) for halogen-based cathodes, and ion storage mechanism optimization for organic hosts. These strategies aim to amplify their inherent multi-electron transfer capabilities while preventing the dissolution of active materials during multi-step redox processes.

Furthermore, exploring novel cathode materials is crucial for developing innovative battery systems. In designing cathodes, principles based on light element multi-electron reactions are employed to achieve high-energy and long-life AZBs, such as transitioning from V2O5 to VO2, and iodine to chlorine or sulfur elements. It is also important to note that cathode-free systems can still achieve high surface capacity and long cycle life by constructing Zn batteries with active substances present in the electrolyte. Additionally, exploring more redox couples that facilitate synergistic oxidation/reduction processes involving both cations and anions could further advance AZB technology. For Mn-based, V-based compounds, organics and halogens, incorporating specific redox couples not only inhibits the generation of deactivated matter for enhanced cycle life but also increases the redox activity for boosted energy density. Therefore, the coupling or mutual excitation of multiple redox reactions between the cathode and the electrolyte, resulting in multiple electron transfers, is the future research trend of Zn batteries. In addition, artificial intelligence (AI) can be used to predict electrode material functions and design structures to efficiently build high-energy density and durable cathode materials. For example, AI can calculate to predict the physical/chemical properties of MnO2 cathodes doped with different transition metals, thereby quickly choosing optimal combination for superior cathode materials with the sensitized MnO2/Mn2+ redox reaction.

AZBs hold the potential to revolutionize the energy storage landscape, offering solutions that address safety concerns, leverage abundant resources, and stand at the forefront of emerging battery technologies. To achieve this potential, however, advanced electrode materials, electrolytes, and cell designs are necessary to be integrated into full zinc-ion battery systems, along with the comprehensive optimization and testing. This process ensures the AZB system meets safety, efficiency, and durability standards, achieving high-energy and long-life Zn batteries based on light-element hosts and multi-electron reactions. Moreover, exploring more redox couples that facilitate synergistic oxidation/reduction processes involving cations and anions could greatly boost the further advancements in AZBs. Besides developing novel cathode materials matched with the optimized electrolyte, understanding the battery degradation mechanisms and operating condition optimization is essential for constructing advanced AZBs. Meanwhile, strategic optimization of battery design is required with targeted modifications to both the Zn anodes and electrolytes, as shown in Figure 6. To mitigate common issues associated with Zn anodes, such as dendritic growth, hydrogen evolution, and corrosion, several strategies can be employed. These include surface coatings or treatments, structural modifications, and the use of advanced materials or anode-free Zn battery systems. Each of these approaches aims to enhance the stability and longevity of the anodes, thereby improving the overall battery performance. Similarly, electrolyte modifications play a critical role in enhancing battery efficiency. Electrolyte additives, regulating pH buffers, temperature control, and redox couples, are pivotal for improving Zn stability, CE, and energy density of Zn batteries. For example, the addition of pH buffers can not only protect the Zn anode from corrosion but also inhibit the side reactions of the cathode for the high reaction efficiency. Therefore, creating a more conducive working environment can greatly optimize the battery performance of AZBs.

High-energy and durable aqueous Zn batteries enabled by multi-electron transfer reactions

Figure 6. Perspectives of the high-energy aqueous Zn batteries enabled by multi-electron transfer reactions.

The successful commercialization and integration of AZBs into our existing energy infrastructure hinge on thorough integration and compatibility studies. These batteries have a wide range of potential applications, from small-scale portable electronics to large electric grids, each with unique requirements and challenges. To this end, scientists and engineers are actively engaged in exploring how Zn battery technology can be seamlessly incorporated into current energy systems, with a vision to foster a more sustainable and energy-efficient future. This review aims to offer insightful perspectives and recommendations for ongoing research in multi-electron transfer AZBs, with the additional goal of stimulating further innovation in this field. The ultimate objective is to realize the full potential of Zn devices, delivering energy storage solutions to meet the diverse needs of modern and future energy demands. By continuing to push the boundaries of this technology, AZBs with multiple electron transfer reactions could play a pivotal role in shaping the energy storage landscape and contribute significantly to global sustainability efforts.


Authors’ contributions

Performed an extensive literature search and information gathering, and subsequently composed the paper: Li Q, Abdalla KK

Managed copyright aspects and associated picture legend: Song Z, Liu M

Revised and modified paper: Xiong J, Wang Y, Zhao Y, Fan Y

Acquired the funding and supervised the entire process: Zhao Y, Sun XM

Availability of data and materials

Not applicable.

Financial support and sponsorship

This work was supported by the National Natural Science Foundation of China (22209006, 21935001), the Natural Science Foundation of Shandong Province (ZR2022QE009), Fundamental Research Funds for the Central Universities (buctrc202307), the National Key Beijing Natural Science Foundation (Z210016), the Fundamental Research Funds for the Central Universities, and the long-term subsidy mechanism from the Ministry of Finance and the Ministry of Education of China.

Conflicts of interest

All authors declared that there are no conflicts of interest.

Ethical approval and consent to participate

Not applicable.

Consent for publication

Not applicable.


© The Author(s) 2024.


1. Han L, Wu Y, Fang K, et al. The splanchnic mesenchyme is the tissue of origin for pancreatic fibroblasts during homeostasis and tumorigenesis. Nat Commun 2023;14:1.

2. Hou D, Xia D, Gabriel E, et al. Spatial and temporal analysis of sodium-ion batteries. ACS Energy Lett 2021;6:4023-54.

3. Xiong P, Lin C, Wei Y, et al. Charge-transfer complex-based artificial layers for stable and efficient Zn metal anodes. ACS Energy Lett 2023;8:2718-27.

4. Xiao D, Lv X, Fan J, Li Q, Chen Z. Zn-based batteries for energy storage. Energy Mater 2023;3:300007.

5. Bruce PG, Freunberger SA, Hardwick LJ, Tarascon JM. Li-O2 and Li-S batteries with high energy storage. Nat Mater 2011;11:19-29.

6. Xia X, Zhao Y, Zhao Y, Xu M, Liu W, Sun X. Mo doping provokes two electron reaction in MnO2 with ultrahigh capacity for aqueous zinc ion batteries. Nano Res 2023;16:2511-8.

7. Zhong Y, Xu X, Veder JP, Shao Z. Self-recovery chemistry and cobalt-catalyzed electrochemical deposition of cathode for boosting performance of aqueous zinc-ion batteries. iScience 2020;23:100943.

8. Liu Y, Wang K, Yang X, Liu J, Liu XX, Sun X. Enhancing two-electron reaction contribution in MnO2 cathode material by structural engineering for stable cycling in aqueous Zn batteries. ACS Nano 2023;17:14792-9.

9. Zhao Y, Xia X, Li Q, et al. Activating the redox chemistry of MnO2/Mn2+ in aqueous Zn batteries based on multi-ions doping regulation. Energy Storage Mater 2024;67:103268.

10. Ma Y, Xu M, Liu R, et al. Molecular tailoring of MnO2 by bismuth doping to achieve aqueous zinc-ion battery with capacitor-level durability. Energy Storage Mater 2022;48:212-22.

11. Wan F, Huang S, Cao H, Niu Z. Freestanding potassium vanadate/carbon nanotube films for ultralong-life aqueous zinc-ion batteries. ACS Nano 2020;14:6752-60.

12. Guo J, He B, Gong W, et al. Emerging amorphous to crystalline conversion chemistry in Ca-Doped VO2 cathodes for high-capacity and long-term wearable aqueous zinc-ion batteries. Adv Mater 2024;36:e2303906.

13. Song Z, Zhao Y, Zhou A, et al. Organic intercalation induced kinetic enhancement of vanadium oxide cathodes for ultrahigh-loading aqueous zinc-ion batteries. Small 2024;20:e2305030.

14. Wang W, Yang C, Chi X, Liu J, Wen B, Liu Y. Ultralow-water-activity electrolyte endows vanadium-based zinc-ion batteries with durable lifespan exceeding 30 000 cycles. Energy Storage Mater 2022;53:774-82.

15. Zou Y, Liu T, Du Q, et al. A four-electron Zn-I2 aqueous battery enabled by reversible I-/I2/I+ conversion. Nat Commun 2021;12:170.

16. Liu H, Chen CY, Yang H, et al. A zinc-dual-halogen battery with a molten hydrate electrolyte. Adv Mater 2020;32:e2004553.

17. Chen Z, Hou Y, Wang Y, et al. Selenium-anchored chlorine redox chemistry in aqueous zinc dual-ion batteries. Adv Mater 2024;36:e2309330.

18. Wang C, Lai Q, Xu P, Zheng D, Li X, Zhang H. Cage-like porous carbon with superhigh activity and Br2-complex-entrapping capability for bromine-based flow batteries. Adv Mater 2017;29:1605815.

19. Zhang SJ, Hao J, Li H, et al. Polyiodide confinement by starch enables shuttle-free Zn-iodine batteries. Adv Mater 2022;34:e2201716.

20. Peng C, Ning G, Su J, et al. Reversible multi-electron redox chemistry of π-conjugated N-containing heteroaromatic molecule-based organic cathodes. Nat Energy 2017;2:17074.

21. Zhao Y, Huang Y, Chen R, Wu F, Li L. Tailoring double-layer aromatic polymers with multi-active sites towards high performance aqueous Zn-organic batteries. Mater Horiz 2021;8:3124-32.

22. Ye F, Liu Q, Dong H, et al. Organic zinc-ion battery: planar, π-conjugated quinone-based polymer endows ultrafast ion diffusion kinetics. Angew Chem Int Ed 2022;61:e202214244.

23. Lu Y, Cai Y, Zhang Q, Chen J. Structure-performance relationships of covalent organic framework electrode materials in metal-ion batteries. J Phys Chem Lett 2021;12:8061-71.

24. Kumankuma-Sarpong J, Tang S, Guo W, Fu Y. Naphthoquinone-based composite cathodes for aqueous rechargeable zinc-ion batteries. ACS Appl Mater Interfaces 2021;13:4084-92.

25. Li Q, Zhao Y, Wang Y, Khasraw AK, Zhao Y, Sun X. Rational design of nanostructured MnO2 cathode for high-performance aqueous zinc ion batteries. Chem Res Chin Univ 2023;39:599-611.

26. Zhao Y, Zhang P, Liang J, et al. Uncovering sulfur doping effect in MnO2 nanosheets as an efficient cathode for aqueous zinc ion battery. Energy Storage Mater 2022;47:424-33.

27. Dai H, Zhou R, Zhang Z, Zhou J, Sun G. Design of manganese dioxide for supercapacitors and zinc-ion batteries: similarities and differences. Energy Mater 2022;2:200040.

28. Dong H, Li J, Guo J, et al. Insights on flexible zinc-ion batteries from lab research to commercialization. Adv Mater 2021;33:e2007548.

29. Wang M, Tang Y. A review on the features and progress of dual-ion batteries. Adv Energy Mater 2018;8:1703320.

30. Wang S, Hu N, Huang Y, Deng W. Charge-transfer complex promotes energy storage performance of single-moiety organic electrode materials in aqueous zinc-ion battery at low temperatures. Appl Surf Sci 2023;619:156725.

31. Xiong P, Kang Y, Yao N, et al. Zn-ion transporting, in situ formed robust solid electrolyte interphase for stable zinc metal anodes over a wide temperature range. ACS Energy Lett 2023;8:1613-25.

32. Wang M, Zheng X, Zhang X, et al. Opportunities of aqueous manganese-based batteries with deposition and stripping chemistry. Adv Energy Mater 2021;11:2002904.

33. Ruan P, Liang S, Lu B, Fan HJ, Zhou J. Design strategies for high-energy-density aqueous zinc batteries. Angew Chem Int Ed 2022;61:e202200598.

34. Li Y, Liu L, Lu Y, et al. High-energy-density quinone-based electrodes with [Al(OTF)] 2+ storage mechanism for rechargeable aqueous aluminum batteries. Adv Funct Mater 2021;31:2102063.

35. Xu Y, Xu X, Guo M, Zhang G, Wang Y. Research progresses and challenges of flexible zinc battery. Front Chem 2022;10:827563.

36. Chen H, Wang C, Dai Y, et al. Rational design of cathode structure for high rate performance lithium-sulfur batteries. Nano Lett 2015;15:5443-8.

37. Xu Y, Xie C, Li T, Li X. A high energy density bromine-based flow battery with two-electron transfer. ACS Energy Lett 2022;7:1034-9.

38. Ge G, Zhang C, Li X. Multi-electron transfer electrode materials for high-energy-density flow batteries. Next Energy 2023;1:100043.

39. Zhao Y, Wang Y, Zhao Z, et al. Achieving high capacity and long life of aqueous rechargeable zinc battery by using nanoporous-carbon-supported poly(1,5-naphthalenediamine) nanorods as cathode. Energy Storage Mater 2020;28:64-72.

40. Huang YX, Wu F, Chen RJ. Thermodynamic analysis and kinetic optimization of high-energy batteries based on multi-electron reactions. Natl Sci Rev 2020;7:1367-86.

41. Gao X, Yang H. Multi-electron reaction materials for high energy density batteries. Energy Environ Sci 2010;3:174-89.

42. Chen R, Luo R, Huang Y, Wu F, Li L. Advanced high energy density secondary batteries with multi-electron reaction materials. Adv Sci 2016;3:1600051.

43. Whittingham MS, Siu C, Ding J. Can multielectron intercalation reactions be the basis of next generation batteries? ACC Chem Res 2018;51:258-64.

44. Guo RQ, Wu F, Wang XR, Wu C, Bai Y. Multi-electron reaction-boosted high energy density batteries: material and system innovation. J Electrochem 2022;28:2219011.

45. Chen W, Li G, Pei A, et al. A manganese-hydrogen battery with potential for grid-scale energy storage. Nat Energy 2018;3:428-35.

46. Chao D, Zhou W, Ye C, et al. An electrolytic Zn-MnO2 battery for high-voltage and scalable energy storage. Angew Chem Int Ed 2019;58:7823-8.

47. Pan H, Shao Y, Yan P, et al. Reversible aqueous zinc/manganese oxide energy storage from conversion reactions. Nat Energy 2016;1:16039.

48. Xie C, Li T, Deng C, Song Y, Zhang H, Li X. A highly reversible neutral zinc/manganese battery for stationary energy storage. Energy Environ Sci 2020;13:135-43.

49. Fu Y, Wei Q, Zhang G, et al. High-performance reversible aqueous Zn-ion battery based on porous MnOx nanorods coated by MOF-derived N-doped carbon. Adv Energy Mater 2018;8:1801445.

50. Radha AV, Forbes TZ, Killian CE, Gilbert PU, Navrotsky A. Transformation and crystallization energetics of synthetic and biogenic amorphous calcium carbonate. Proc Natl Acad Sci USA 2010;107:16438-43.

51. Huang J, Zeng J, Zhu K, Zhang R, Liu J. High-performance aqueous zinc-manganese battery with reversible Mn2+/Mn4+ double redox achieved by carbon coated MnOx nanoparticles. Nanomicro Lett 2020;12:110.

52. Moon H, Ha KH, Park Y, et al. Direct proof of the reversible dissolution/deposition of Mn2+/Mn4+ for mild-acid Zn-MnO2 batteries with porous carbon interlayers. Adv Sci 2021;8:2003714.

53. Yang H, Zhang T, Chen D, et al. Protocol in evaluating capacity of Zn-Mn aqueous batteries: a clue of pH. Adv Mater 2023;35:e2300053.

54. Yang H, Zhou W, Chen D, et al. The origin of capacity fluctuation and rescue of dead Mn-based Zn-ion batteries: a Mn-based competitive capacity evolution protocol. Energy Environ Sci 2022;15:1106-18.

55. Xu Y, Huang W, Liu J, et al. Promoting the reversibility of electrolytic MnO2 -Zn battery with high areal capacity by VOSO4 mediator. Energy Mater 2024;4:400005.

56. Ma D, Zhao H, Cao F, et al. A carbonyl-rich covalent organic framework as a high-performance cathode material for aqueous rechargeable zinc-ion batteries. Chem Sci 2022;13:2385-90.

57. Rubio-garcia J, Kucernak A, Zhao D, et al. Hydrogen/manganese hybrid redox flow battery. J Phys Energy 2019;1:015006.

58. Liu Z, Yang Y, Lu B, Liang S, Fan HJ, Zhou J. Insights into complexing effects in acetate-based Zn-MnO2 batteries and performance enhancement by all-round strategies. Energy Storage Mater 2022;52:104-10.

59. Ye X, Han D, Jiang G, et al. Unraveling the deposition/dissolution chemistry of MnO2 for high-energy aqueous batteries. Energy Environ Sci 2023;16:1016-23.

60. Wu J, Huang J, Chi X, Yang J, Liu Y. Mn2+/I- hybrid cathode with superior conversion efficiency for ultrahigh-areal-capacity aqueous zinc batteries. ACS Appl Mater Interfaces 2022;14:53627-35.

61. Lei J, Yao Y, Wang Z, Lu Y. Towards high-areal-capacity aqueous zinc-manganese batteries: promoting MnO2 dissolution by redox mediators. Energy Environ Sci 2021;14:4418-26.

62. Chuai M, Yang J, Wang M, et al. High-performance Zn battery with transition metal ions co-regulated electrolytic MnO2. eScience 2021;1:178-85.

63. Li G, Chen W, Zhang H, et al. Membrane-free Zn/MnO2 flow battery for large-scale energy storage. Adv Energy Mater 2020;10:1902085.

64. Tang H, Yin Y, Huang Y, et al. Battery-everywhere design based on a cathodeless configuration with high sustainability and energy density. ACS Energy Lett 2021;6:1859-68.

65. Alfaruqi MH, Mathew V, Gim J, et al. Electrochemically induced structural transformation in a γ-MnO2 cathode of a high capacity zinc-ion battery system. Chem Mater 2015;27:3609-20.

66. Lee B, Seo HR, Lee HR, et al. Critical role of pH evolution of electrolyte in the reaction mechanism for rechargeable zinc batteries. ChemSusChem 2016;9:2948-56.

67. Liu W, Zhang X, Huang Y, et al. β-MnO2 with proton conversion mechanism in rechargeable zinc ion battery. J Energy Chem 2021;56:365-73.

68. Fitz O, Bischoff C, Bauer M, et al. Electrolyte study with in operando pH tracking providing insight into the reaction mechanism of aqueous acidic Zn/MnO2 batteries. ChemElectroChem 2021;8:3553-66.

69. Wu D, Housel LM, Kim SJ, et al. Quantitative temporally and spatially resolved X-ray fluorescence microprobe characterization of the manganese dissolution-deposition mechanism in aqueous Zn/α-MnO2 batteries. Energy Environ Sci 2020;13:4322-33.

70. Kim SJ, Wu D, Sadique N, et al. Unraveling the dissolution-mediated reaction mechanism of α-MnO2 cathodes for aqueous Zn-ion batteries. Small 2020;16:e2005406.

71. Chen H, Dai C, Xiao F, et al. Reunderstanding the reaction mechanism of aqueous Zn-Mn batteries with sulfate electrolytes: role of the zinc sulfate hydroxide. Adv Mater 2022;34:e2109092.

72. Guo S, Liang S, Zhang B, Fang G, Ma D, Zhou J. Cathode interfacial layer formation via in situ electrochemically charging in aqueous zinc-ion battery. ACS Nano 2019;13:13456-64.

73. Jiang W, Zhu K, Yang W. Critical issues of vanadium-based cathodes towards practical aqueous Zn-ion batteries. Chemistry 2023;29:e202301769.

74. Hu Z, Miao Z, Xu Z, et al. Carbon felt electrode modified by lotus seed shells for high-performance vanadium redox flow battery. Chem Eng J 2022;450:138377.

75. Jiang H, Chen GF, Hai G, et al. A nitrogen battery electrode involving eight-electron transfer per nitrogen for energy storage. Angew Chem Int Ed 2023;62:e202305695.

76. Venkatkarthick R, Rodthongkum N, Zhang X, et al. Vanadium-based oxide on two-dimensional vanadium carbide MXene (V2Ox@V2CTx) as cathode for rechargeable aqueous zinc-ion batteries. ACS Appl Energy Mater 2020;3:4677-89.

77. Zhu X, Wang W, Cao Z, et al. Zn2+-intercalated V2O5·nH2O derived from V2CTx MXene for hyper-stable zinc-ion storage. J Mater Chem A 2021;9:17994-8005.

78. Wu S, Liu S, Hu L, Chen S. Constructing electron pathways by graphene oxide for V2O5 nanoparticles in ultrahigh-performance and fast charging aqueous zinc ion batteries. J Alloys Compd 2021;878:160324.

79. Wang X, Li Y, Das P, Zheng S, Zhou F, Wu Z. Layer-by-layer stacked amorphous V2O5/Graphene 2D heterostructures with strong-coupling effect for high-capacity aqueous zinc-ion batteries with ultra-long cycle life. Energy Storage Mater 2020;31:156-63.

80. Cui F, Wang D, Hu F, et al. Deficiency and surface engineering boosting electronic and ionic kinetics in NH4V4O10 for high-performance aqueous zinc-ion battery. Energy Storage Mater 2022;44:197-205.

81. Narayanasamy M, Hu L, Kirubasankar B, Liu Z, Angaiah S, Yan C. Nanohybrid engineering of the vertically confined marigold structure of rGO-VSe2 as an advanced cathode material for aqueous zinc-ion battery. J Alloys Compd 2021;882:160704.

82. Deka Boruah B, Mathieson A, Park SK, et al. Vanadium dioxide cathodes for high-rate photo-rechargeable zinc-ion batteries. Adv Energy Mater 2021;11:2100115.

83. Kong D, Li X, Zhang Y, et al. Encapsulating V2O5 into carbon nanotubes enables the synthesis of flexible high-performance lithium ion batteries. Energy Environ Sci 2016;9:906-11.

84. Wan F, Niu Z. Design strategies for vanadium-based aqueous zinc-ion batteries. Angew Chem Int Ed 2019;58:16358-67.

85. Guo C, Yi S, Si R, et al. Advances on defect engineering of vanadium-based compounds for high-energy aqueous zinc-ion batteries. Adv Energy Mater 2022;12:2202039.

86. Deng S, Jiang Y, Huang D, et al. Driving intercalation kinetic through hydrated Na+ insertion in V2O5 for high rate performance aqueous zinc ion batteries. J Alloys Compd 2022;891:161946.

87. Ma X, Cao X, Yao M, et al. Organic-inorganic hybrid cathode with dual energy-storage mechanism for ultrahigh-rate and ultralong-life aqueous zinc-ion batteries. Adv Mater 2022;34:e2105452.

88. Islam S, Alfaruqi MH, Putro DY, et al. K+ intercalated V2O5 nanorods with exposed facets as advanced cathodes for high energy and high rate zinc-ion batteries. J Mater Chem A 2019;7:20335-47.

89. Sambandam B, Soundharrajan V, Kim S, et al. K2V6O16·2.7H2O nanorod cathode: an advanced intercalation system for high energy aqueous rechargeable Zn-ion batteries. J Mater Chem A 2018;6:15530-9.

90. He P, Quan Y, Xu X, et al. High-performance aqueous zinc-ion battery based on layered H2V3O8 nanowire cathode. Small 2017;13:1702551.

91. Peng B, Zhang H, Shao H, et al. Chemical intuition for high thermoelectric performance in monolayer black phosphorus, α-arsenene and aW-antimonene. J Mater Chem A 2018;6:2018-33.

92. Wang X, Zhang Z, Xiong S, et al. A high-rate and ultrastable aqueous zinc-ion battery with a novel MgV2O6·1.7H2O nanobelt cathode. Small 2021;17:e2100318.

93. Yang Y, Guo S, Pan Y, Lu B, Liang S, Zhou J. Dual mechanism of ion (de)intercalation and iodine redox towards advanced zinc batteries. Energy Environ Sci 2023;16:2358-67.

94. Liang G, Liang B, Chen A, et al. Development of rechargeable high-energy hybrid zinc-iodine aqueous batteries exploiting reversible chlorine-based redox reaction. Nat Commun 2023;14:1856.

95. Wang H, Chen S, Fu C, et al. Recent advances in conversion-type electrode materials for post lithium-ion batteries. ACS Mater Lett 2021;3:956-77.

96. Kang J, Zhao Z, Li H, Meng Y, Hu B, Lu H. An overview of aqueous zinc-ion batteries based on conversion-type cathodes. Energy Mater 2022;2:200009.

97. Kralik D, Jorne J. Hydrogen evolution and zinc nodular growth in the zinc chloride battery. J Electrochem Soc 1980;127:2335-40.

98. Gao L, Li Z, Zou Y, et al. A high-performance aqueous zinc-bromine static battery. iScience 2020;23:101348.

99. Li Y, Liu L, Li H, Cheng F, Chen J. Rechargeable aqueous zinc-iodine batteries: pore confining mechanism and flexible device application. Chem Commun 2018;54:6792-5.

100. Ma W, Liu T, Xu C, et al. A twelve-electron conversion iodine cathode enabled by interhalogen chemistry in aqueous solution. Nat Commun 2023;14:5508.

101. Darling RM, Gallagher KG, Kowalski JA, Ha S, Brushett FR. Pathways to low-cost electrochemical energy storage: a comparison of aqueous and nonaqueous flow batteries. Energy Environ Sci 2014;7:3459-77.

102. Biswas S, Senju A, Mohr R, et al. Minimal architecture zinc-bromine battery for low cost electrochemical energy storage. Energy Environ Sci 2017;10:114-20.

103. Zhu G, Tian X, Tai HC, et al. Rechargeable Na/Cl2 and Li/Cl2 batteries. Nature 2021;596:525-30.

104. Yang C, Chen J, Ji X, et al. Aqueous Li-ion battery enabled by halogen conversion-intercalation chemistry in graphite. Nature 2019;569:245-50.

105. Kim JT, Jorné J. The kinetics of a chlorine graphite electrode in the zinc-chlorine battery. J Electrochem Soc 1977;124:1473-7.

106. Fan X, Huang K, Chen L, et al. High power- and energy-density supercapacitors through the chlorine respiration mechanism. Angew Chem Int Ed 2023;62:e202215342.

107. Holleck GL. The reduction of chlorine on carbon in AlCl3-KCl-NaCl melts. J Electrochem Soc 1972;119:1158.

108. Chen N, Wang W, Ma Y, et al. Aqueous zinc-chlorine battery modulated by a MnO2 redox adsorbent. Small Methods 2023:e2201553.

109. Lin D, Li Y. Recent advances of aqueous rechargeable zinc-iodine batteries: challenges, solutions, and prospects. Adv Mater 2022;34:e2108856.

110. Eustace DJ. Bromine complexation in zinc-bromine circulating batteries. J Electrochem Soc 1980;127:528-32.

111. Jameson A, Gyenge E. Halogens as positive electrode active species for flow batteries and regenerative fuel cells. Electrochem Energ Rev 2020;3:431-65.

112. Pei Z, Zhu Z, Sun D, et al. Review of the I-/I3- redox chemistry in Zn-iodine redox flow batteries. Mater Res Bull 2021;141:111347.

113. Miao L, Guo Z, Jiao L. Insights into the design of mildly acidic aqueous electrolytes for improved stability of Zn anode performance in zinc-ion batteries. Energy Mater 2023;3:300014.

114. Yin Y, Yuan Z, Li X. Rechargeable aqueous zinc-bromine batteries: an overview and future perspectives. Phys Chem Chem Phys 2021;23:26070-84.

115. Mahmood A, Zheng Z, Chen Y. Zinc-bromine batteries: challenges, prospective solutions, and future. Adv Sci 2024;11:e2305561.

116. Xiang HX, Tan AD, Piao JH, Fu ZY, Liang ZX. Efficient nitrogen-doped carbon for zinc-bromine flow battery. Small 2019;15:e1901848.

117. Wang C, Li X, Xi X, Xu P, Lai Q, Zhang H. Relationship between activity and structure of carbon materials for Br2/Br- in zinc bromine flow batteries. RSC Adv 2016;6:40169-74.

118. Suresh S, Ulaganathan M, Venkatesan N, Periasamy P, Ragupathy P. High performance zinc-bromine redox flow batteries: role of various carbon felts and cell configurations. J Energy Storage 2018;20:134-9.

119. Suresh S, Ulaganathan M, Aswathy R, Ragupathy P. Enhancement of bromine reversibility using chemically modified electrodes and their applications in zinc bromine hybrid redox flow batteries. ChemElectroChem 2018;5:3411-8.

120. Xu C, Lei C, Jiang P, et al. Practical high-energy aqueous zinc-bromine static batteries enabled by synergistic exclusion-complexation chemistry. Joule 2024;8:461-81.

121. Park H, Bera RK, Ryoo R. Microporous 3D graphene-like carbon as iodine host for zinc-based battery-supercapacitor hybrid energy storage with ultrahigh energy and power densities. Adv Energy Sustain Res 2021;2:2100076.

122. Liu T, Wang H, Lei C, et al. Recognition of the catalytic activities of graphitic N for zinc-iodine batteries. Energy Storage Mater 2022;53:544-51.

123. Bai C, Cai F, Wang L, Guo S, Liu X, Yuan Z. A sustainable aqueous Zn-I2 battery. Nano Res 2018;11:3548-54.

124. Liu M, Chen Q, Cao X, Tan D, Ma J, Zhang J. Physicochemical confinement effect enables high-performing zinc-iodine batteries. J Am Chem Soc 2022;144:21683-91.

125. Tan Y, Tao Z, Zhu Y, et al. Anchoring I3- via charge-transfer interaction by a coordination supramolecular network cathode for a high-performance aqueous dual-ion battery. ACS Appl Mater Interfaces 2022;14:47716-24.

126. Zeng X, Meng X, Jiang W, et al. Anchoring polyiodide to conductive polymers as cathode for high-performance aqueous zinc-iodine batteries. ACS Sustain Chem Eng 2020;8:14280-5.

127. Chen M, Zhu W, Guo H, et al. Tightly confined iodine in surface-oxidized carbon matrix toward dual-mechanism zinc-iodine batteries. Energy Storage Mater 2023;59:102760.

128. Yang H, Qiao Y, Chang Z, Deng H, He P, Zhou H. A metal-organic framework as a multifunctional ionic sieve membrane for long-life aqueous zinc-iodide batteries. Adv Mater 2020;32:e2004240.

129. Shang W, Zhu J, Liu Y, et al. Establishing high-performance quasi-solid Zn/I2 batteries with alginate-based hydrogel electrolytes. ACS Appl Mater Interfaces 2021;13:24756-64.

130. Sonigara KK, Zhao J, Machhi HK, Cui G, Soni SS. Self-assembled solid-state gel catholyte combating iodide diffusion and self-discharge for a stable flexible aqueous Zn-I2 Battery. Adv Energy Mater 2020;10:2001997.

131. Chen G, Kang Y, Yang H, et al. Toward forty thousand-cycle aqueous zinc-iodine battery: simultaneously inhibiting polyiodides shuttle and stabilizing zinc anode through a suspension electrolyte. Adv Funct Mater 2023;33:2300656.

132. Wang Z, Meng X, Chen K, Mitra S. Development of high-capacity periodate battery with three-dimensional-printed casing accommodating replaceable flexible electrodes. ACS Appl Mater Interfaces 2018;10:30257-64.

133. Wang A, Gyenge EL. Borohydride electro-oxidation in a molten alkali hydroxide eutectic mixture and a novel borohydride-periodate battery. J Power Sources 2015;282:169-73.

134. Wang Z, Meng X, Chen K, Mitra S. High capacity aqueous periodate batteries featuring a nine-electron transfer process. Energy Storage Mater 2019;19:206-11.

135. Shi Y, Chen Y, Shi L, et al. An overview and future perspectives of rechargeable zinc batteries. Small 2020;16:e2000730.

136. Grignon E, Battaglia AM, Schon TB, Seferos DS. Aqueous zinc batteries: design principles toward organic cathodes for grid applications. iScience 2022;25:104204.

137. Yan Y, Li P, Wang Y, et al. Molecular engineering of N-heteroaromatic organic cathode for high-voltage and highly stable zinc batteries. Adv Funct Mater 2024:2312332.

138. Chen W, Chen T, Fu J. Pivotal role of organic materials in aqueous zinc-based batteries: regulating cathode, anode, electrolyte, and separator. Adv Funct Mater 2024;34:2308015.

139. Zhang X, Zhang L, Jia X, Song W, Liu Y. Design strategies for aqueous zinc metal batteries with high zinc utilization: from metal anodes to anode-free structures. Nanomicro Lett 2024;16:75.

140. Cui H, Ma L, Huang Z, Chen Z, Zhi C. Organic materials-based cathode for zinc ion battery. SmartMat 2022;3:565-81.

141. Huang L, Li J, Wang J, et al. Organic compound as a cathode for aqueous zinc-ion batteries with improved electrochemical performance via multiple active centers. ACS Appl Energy Mater 2022;5:15780-7.

142. Abdalla KK, Wang Y, Abdalla KK, et al. Rational design and prospects for advanced aqueous Zn-organic batteries enabled by multielectron redox reactions. Sci China Mater 2024;67:1367-78.

143. Yang B, Ma Y, Bin D, Lu H, Xia Y. Ultralong-life cathode for aqueous zinc-organic batteries via pouring 9,10-phenanthraquinone into active carbon. ACS Appl Mater Interfaces 2021;13:58818-26.

144. Yan L, Zhang Y, Ni Z, et al. Chemically self-charging aqueous zinc-organic battery. J Am Chem Soc 2021;143:15369-77.

145. Li Z, Tan J, Wang Y, et al. Building better aqueous Zn-organic batteries. Energy Environ Sci 2023;16:2398-431.

146. Wang Y, Li Q, Li Q, et al. Design strategies and challenges of next generation aqueous Zn-organic batteries. Next Energy 2023;1:100061.

147. Li W, Xu H, Zhang H, et al. Tuning electron delocalization of hydrogen-bonded organic framework cathode for high-performance zinc-organic batteries. Nat Commun 2023;14:5235.

148. Lee M, Hong J, Lee B, et al. Multi-electron redox phenazine for ready-to-charge organic batteries. Green Chem 2017;19:2980-5.

149. Lin Q, Li H, Chen L, He X. Naphthalenediimide-carbonylpyridiniums: stable six electron acceptors for organic cathodes. Mater Chem Front 2023;7:3747-53.

150. Zhao Y, Zhang S, Zhang Y, et al. Vacancy-rich Al-doped MnO2 cathodes break the trade-off between kinetics and stability for high-performance aqueous Zn-ion batteries. Energy Environ Sci 2024;17:1279-90.

151. Zhong Y, Li Y, Meng J, et al. Boosting the cyclability of tetracyanoquinodimethane (TCNQ) as cathode material in aqueous battery with high valent cation. Energy Storage Mater 2021;43:492-8.

152. Cheng M, Zheng S, Sun T, et al. A solubility limited pyrene-4,5,9,10-tetraone-based covalent organic framework for high-performance aqueous zinc-organic batteries. Nano Res 2024;17:5095-103.

153. Zuo S, Xu X, Ji S, Wang Z, Liu Z, Liu J. Cathodes for aqueous Zn-ion batteries: materials, mechanisms, and kinetics. Chemistry 2021;27:830-60.

154. Ji W, Du D, Liang J, et al. Aqueous Zn-organic batteries: electrochemistry and design strategies. Battery Energy 2023;2:20230020.

155. Sun T, Yi Z, Zhang W, Nian Q, Fan HJ, Tao Z. Dynamic balance of partial charge for small organic compound in aqueous zinc-organic battery. Adv Funct Mater 2023;33:2306675.

156. Gong Y, Wang B, Ren H, et al. Recent advances in structural optimization and surface modification on current collectors for high-performance zinc anode: principles, strategies, and challenges. Nanomicro Lett 2023;15:208.

157. Li J, Huang L, Lv H, et al. Novel organic cathode with conjugated N-heteroaromatic structures for high-performance aqueous zinc-ion batteries. ACS Appl Mater Interfaces 2022;14:38844-53.

158. Wang Y, Wang C, Ni Z, et al. Binding zinc ions by carboxyl groups from adjacent molecules toward long-life aqueous zinc-organic batteries. Adv Mater 2020;32:e2000338.

159. Lin Z, Shi HY, Lin L, Yang X, Wu W, Sun X. A high capacity small molecule quinone cathode for rechargeable aqueous zinc-organic batteries. Nat Commun 2021;12:4424.

160. Zheng S, Wang Q, Hou Y, Li L, Tao Z. Recent progress and strategies toward high performance zinc-organic batteries. J Energy Chem 2021;63:87-112.

161. Chen Y, Fan K, Gao Y, Wang C. Challenges and perspectives of organic multivalent metal-ion batteries. Adv Mater 2022;34:e2200662.

162. Peng H, Xiao J, Wu Z, et al. N-heterocycles extended π-conjugation enables ultrahigh capacity, long-lived, and fast-charging organic cathodes for aqueous zinc batteries. CCS Chem 2023;5:1789-801.

163. Zhang M, Ding C, Li C, et al. Bioactive small-molecule-based aqueous zinc-organic battery enables long-life and fast-charge performance. Sci China Mater 2023;66:3104-12.

164. Zhao Y, Huang Y, Wu F, Chen R, Li L. High-performance aqueous zinc batteries based on organic/organic cathodes integrating multiredox centers. Adv Mater 2021;33:e2106469.

165. Xu D, Zhang H, Cao Z, et al. High-rate aqueous zinc-ion batteries enabled by a polymer/graphene composite cathode involving reversible electrolyte anion doping/dedoping. J Mater Chem A 2021;9:10666-71.

166. Sun T, Fan HJ. Understanding cathode materials in aqueous zinc-organic batteries. Curr Opin Electrochem 2021;30:100799.

167. Song Z, Miao L, Duan H, et al. Anionic co-insertion charge storage in dinitrobenzene cathodes for high-performance aqueous zinc-organic batteries. Angew Chem Int Ed 2022;61:e202208821.

168. Shuai H, Liu R, Li W, et al. Recent advances of transition metal sulfides/selenides cathodes for aqueous zinc-ion batteries. Adv Energy Mater 2023;13:2202992.

169. Ye Z, Xie S, Cao Z, et al. High-rate aqueous zinc-organic battery achieved by lowering HOMO/LUMO of organic cathode. Energy Storage Mater 2021;37:378-86.

170. Chen X, Su H, Yang B, Yin G, Liu Q. Realizing high-rate aqueous zinc-ion batteries using organic cathode materials containing electron-withdrawing groups. Sustain Energy Fuels 2022;6:2523-31.

171. Chen Z, Cui H, Hou Y, et al. Anion chemistry enabled positive valence conversion to achieve a record high-voltage organic cathode for zinc batteries. Chem 2022;8:2204-16.

172. Bayaguud A, Luo X, Fu Y, Zhu C. Cationic surfactant-type electrolyte additive enables three-dimensional dendrite-free zinc anode for stable zinc-ion batteries. ACS Energy Lett 2020;5:3012-20.

173. Dai C, Hu L, Chen H, et al. Enabling fast-charging selenium-based aqueous batteries via conversion reaction with copper ions. Nat Commun 2022;13:1863.

174. Cui F, Pan R, Su L, et al. Activating selenium cathode chemistry for aqueous zinc-ion batteries. Adv Mater 2023;35:e2306580.

175. Zhang Q, Ma Y, Lu Y, et al. Halogenated Zn2+ solvation structure for reversible Zn metal batteries. J Am Chem Soc 2022;144:18435-43.

176. Lin Z, Lin L, Zhu J, Wu W, Yang X, Sun X. An anti-aromatic covalent organic framework cathode with dual-redox centers for rechargeable aqueous zinc batteries. ACS Appl Mater Interfaces 2022;14:38689-95.

177. Xiong P, Zhang Y, Zhang J, et al. Recent progress of artificial interfacial layers in aqueous Zn metal batteries. EnergyChem 2022;4:100076.

Cite This Article

Export citation file: BibTeX | RIS

OAE Style

Li Q, Abdalla KK, Xiong J, Song Z, Wang Y, Zhao Y, Liu M, Fan Y, Zhao Y, Sun XM. High-energy and durable aqueous Zn batteries enabled by multi-electron transfer reactions. Energy Mater 2024;4:400040.

AMA Style

Li Q, Abdalla KK, Xiong J, Song Z, Wang Y, Zhao Y, Liu M, Fan Y, Zhao Y, Sun XM. High-energy and durable aqueous Zn batteries enabled by multi-electron transfer reactions. Energy Materials. 2024; 4(4): 400040.

Chicago/Turabian Style

Li, Qi, Kovan Khasraw Abdalla, Jiawei Xiong, Zhihang Song, Yueyang Wang, Yajun Zhao, Mengyao Liu, Yanchen Fan, Yi Zhao, Xiao-Ming Sun. 2024. "High-energy and durable aqueous Zn batteries enabled by multi-electron transfer reactions" Energy Materials. 4, no.4: 400040.

ACS Style

Li, Q.; Abdalla KK.; Xiong J.; Song Z.; Wang Y.; Zhao Y.; Liu M.; Fan Y.; Zhao Y.; Sun X.M. High-energy and durable aqueous Zn batteries enabled by multi-electron transfer reactions. Energy Mater. 2024, 4, 400040.

About This Article

Special Issue

This article belongs to the Special Issue Aqueous Batteries: Materials, Mechanisms, and Applications
© The Author(s) 2024. Open Access This article is licensed under a Creative Commons Attribution 4.0 International License (, which permits unrestricted use, sharing, adaptation, distribution and reproduction in any medium or format, for any purpose, even commercially, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.

Data & Comments




Comments must be written in English. Spam, offensive content, impersonation, and private information will not be permitted. If any comment is reported and identified as inappropriate content by OAE staff, the comment will be removed without notice. If you have any queries or need any help, please contact us at

Download PDF
Cite This Article 2 clicks
Like This Article 3 likes
Share This Article
Scan the QR code for reading!
See Updates
Energy Materials
ISSN 2770-5900 (Online)
Follow Us


All published articles are preserved here permanently:


All published articles are preserved here permanently: