Rational Design of Functional Electrolytes Towards Commercial Dual-Ion Batteries

Electrolyte solution chemistry and interface dynamics for fast-charging sustainable anion shuttle batteries

The demand for sustainable and fast-charging energy storage systems has grown significantly, yet traditional lithium-ion batteries (LIBs) face challenges related to costly resources and sluggish charge transport kinetics. As a promising alternative, dual-ion batteries (DIBs), also known as anion-shuttle batteries, have gained attention for their high operational voltage and ultrafast charging capabilities. Unlike conventional rocking-chair batteries, DIBs utilize both cations and anions as charge carriers, reducing rate-limiting steps and eliminating long-range ion migration. This review provides a comprehensive analysis of the critical factors influencing DIB performance, with a particular focus on anion solvation structures, diffusion kinetics, electrolyte stability, and interfacial charge transfer mechanisms. We also explore how interface engineering enhances charge transfer efficiency and extends battery lifespan. In particular, we examine the role of cathode electrolyte interphase (CEI) and solvation dynamics in stabilizing the electrode-electrolyte interface. By providing a comprehensive understanding of chemistry and dynamics in DIBs, this review outlines future research directions for advancing sustainable DIBs technology.

Utilization and Advancement of an Electrolyte Containing Mixed Electrolyte Salts in Electrochemical Energy Storage Devices Mainly Based on Lithium-Ion Batteries

An electrolyte salt as an indispensable component has a dramatic impact on the performance of electrochemical energy storage devices. However, every electrolyte salt cannot satisfy all the needs of an electrolyte for rechargeable batteries. For example, in lithium-ion batteries, shortages like the decomposition of the lithium hexafluorophosphate (LiPF6)-based electrolyte at high temperature, the corrosion to the Al cathodic current collector of the lithium difluorosulfonamide (LiFSI)- or lithium bistrifluoromethanesulfonylimide (LiTFSI)-based electrolyte, the low conductivity of the lithium tetrafluoroborate (LiBF4)-based electrolyte, and the inappropriately stable electrochemical windows of the lithium difluorooxalateborate (LiDFOB)- or lithium bisoxalatoborate (LiBOB)-based electrolyte restrict further development of the single lithium salt-based electrolyte for the rechargeable batteries. In this case, much effort has been spent in overcoming the inherent shortage of each electrolyte salt, in which the strategy of mixing an electrolyte salt is attracting growing attention. Herein, an overview about the research progress surrounding the mixed electrolyte salts is presented, including the effect of mixed electrolyte salts on the property's optimization of the electrolyte, the performance of the Al current collector, various cathodes, next-generation anodes, and full batteries. This review aims to elucidate the role of a mixed electrolyte salt in how it influences the battery's components, ultimately changing the performance of various rechargeable batteries.

Low-Concentration Electrolyte Engineering for Rechargeable Batteries

Low-concentration electrolytes (LCEs) present significant potential for actual applications because of their cost-effectiveness, low viscosity, reduced side reactions, and wide-temperature electrochemical stability. However, current electrolyte research predominantly focuses on regulation strategies for conventional 1 m electrolytes, high-concentration electrolytes, and localized high-concentration electrolytes, leaving design principles, optimization methods, and prospects of LCEs inadequately summarized. LCEs face unique challenges that cannot be addressed by the existing theories and approaches applicable to the three common electrolytes mentioned above; thus, tailored strategies to provide development guidance are urgently needed. Herein, a systematic overview of recent progress in LCEs is provided and subsequent development directions are suggested. This review proposes the core challenge of the high solvent ratio in LCEs, which triggers unstable organic-enriched electrolyte/electrode interface formation and anion depletion near the anode. On the basis of these issues, modification strategies for LCEs, including passivation interface construction and solvent‒anion interaction optimization, are used in various rechargeable battery systems. Finally, the role of advanced simulations and cutting-edge characterization techniques in revealing LCE failure mechanisms is further highlighted, offering new perspectives for their future development and practical application in next-generation rechargeable batteries.

Electrolyte Design via Cation-Anion Association Regulation for High-Rate and Dendrite-Free Zinc Metal Batteries at Low Temperature

Low-temperature zinc metal batteries (ZMBs) are highly challenged by Zn dendrite growth, especially at high current density. Here, starting from the intermolecular insights, we report a cation-anion association modulation strategy by matching different dielectric constant solvents and unveil the relationship between cation-anion association strength and Zn plating/stripping performance at low temperatures. The combination of comprehensive characterizations and theoretical calculations indicates that moderate ion association electrolytes with high ionic conductivity (12.09 mS cm-1 at -40 °C) and a stable anion-derived solid electrolyte interphase (SEI) jointly account for highly reversible and dendrite-free Zn plating/stripping behavior, resulting in high-rate and ultrastable cycle performance at low temperature. As a result, at -40 °C, Zn//Zn cells can stably cycle over 400 h at 5 mA cm-2 and 10 mAh cm-2 and Zn//Cu cells exhibit an exceptional average Coulombic efficiency (CE) of 99.91% for 1800 cycles at 1 mA cm-2 and 1 mAh cm-2. Benefiting from enhanced low-temperature Zn plating/stripping performance, Zn//PANI full cells stably operate for 12,000 cycles at 0.5A g-1 and 35,000 cycles at 5 A g-1. Impressively, at -60 °C, Zn//Cu cells still display a high average CE of 99.68% for 2000 cycles. This work underscores the crucial effect of cation-anion association regulation for high-rate and dendrite-free Zn metal anodes, deepening the understanding of intermolecular interaction insights for low-temperature electrolyte design.

Sustainable Dual-Ion Batteries beyond Li

The limitations of resources used in current Li-ion batteries may hinder their widespread use in grid-scale energy storage systems, prompting the search for low-cost and resource-abundant alternatives. "Beyond-Li cation" batteries have emerged as promising contenders; however, they confront noteworthy challenges due to the scarcity of suitable host materials for these cations. In contrast, anions, the other crucial component in electrolytes, demonstrate reversible intercalation capacity in specific materials like graphite. The convergence of anion and cation storage has given rise to a new battery technology known as dual-ion batteries (DIBs). This comprehensive review presents the current status, advancements, and future prospects of sustainable DIBs beyond Li. Notably, most DIBs exhibit similar cathode reaction mechanisms involving anion intercalation, while the distinguishing factor lies in the cation types functioning at the anode. Accordingly, the review is organized into sections by various cation types, including Na-, K-, Mg-, Zn-, Ca-, Al-, NH4 + -, and proton-based DIBs. Moreover, a perspective on these novel DIBs is presented, along with proposed protocols for investigating DIBs and promising future research directions. It is envisioned that this review will inspire fresh concepts, ideas, and research directions, while raising important questions to further tailor and understand sustainable DIBs, ultimately facilitating their practical realization.

A Bio-Inspired Methylation Approach to Salt-Concentrated Hydrogel Electrolytes for Long-Life Rechargeable Batteries

Hydrogel electrolytes hold great promise in developing flexible and safe batteries, but the presence of free solvent water makes battery chemistries constrained by H2 evolution and electrode dissolution. Although maximizing salt concentration is recognized as an effective strategy to reduce water activity, the protic polymer matrices in classical hydrogels are occupied with hydrogen-bonding and barely involved in the salt dissolution, which sets limitations on realizing stable salt-concentrated environments before polymer-salt phase separation occurs. Inspired by the role of protein methylation in regulating intracellular phase separation, here we transform the "inert" protic polymer skeletons into aprotic ones through methylation modification to weaken the hydrogen-bonding, which releases free hydrogen bond acceptors as Lewis base sites to participate in cation solvation and thus assist salt dissolution. An unconventionally salt-concentrated hydrogel electrolyte reaching a salt fraction up to 44 mol % while retaining a high Na+ /H2 O molar ratio of 1.0 is achieved without phase separation. Almost all water molecules are confined in the solvation shell of Na+ with depressed activity and mobility, which addresses water-induced parasitic reactions that limit the practical rechargeability of aqueous sodium-ion batteries. The assembled Na3 V2 (PO4 )3 //NaTi2 (PO4 )3 cell maintains 82.8 % capacity after 580 cycles, which is the longest cycle life reported to date.

Cation Co-Intercalation with Anions: The Origin of Low Capacities of Graphite Cathodes in Multivalent Electrolytes

Dual-ion batteries involving anion intercalation into graphite cathodes represent promising battery technologies for low-cost and high-power energy storage. However, the fundamental origins regarding much lower capacities of graphite cathodes in earth abundant and inexpensive multivalent electrolytes than in Li-ion electrolytes remain elusive. Herein, we reveal that the limited anion-storage capacity of a graphite cathode in multivalent electrolytes is rooted in the abnormal multivalent-cation co-intercalation with anions in the form of large-sized anionic complexes. This cation co-intercalation behavior persists throughout the stage evolution of graphite intercalation compounds and leads to a significant decrease of sites practically viable for capacity contribution inside graphite galleries. Further systematic studies illustrate that the phenomenon of cation co-intercalation into graphite is closely related to the high energy penalty of interfacial anion desolvation due to the strong cation-anion association prevalent in multivalent electrolytes. Leveraging this understanding, we verify that promoting ionic dissociation in multivalent electrolytes by employing high-permittivity and oxidation-tolerant co-solvents is effective in suppressing multivalent-cation co-intercalation and thus achieving increased capacity of graphite cathodes. For instance, introducing adiponitrile as a co-solvent to a Mg²⁺-based carbonate electrolyte leads to 83% less Mg²⁺ co-intercalation and a ∼29.5% increase in delivered capacity of the graphite cathode.