# Probing Electrode–Electrolyte Synergy and Bottleneck Breakthrough of Zinc-Ion Capacitors from Two Key Configurations

**Authors:** Yudan Zhang, Hengyuan Hu, Yufeng Yan, Yuankai Huang, Yongbiao Mu, Zhiyu Zou, Kunxiong Zheng, Zhaoyang Yi, Yang Zhao, Miao Zhang, Lin Zeng, Meisheng Han

PMC · DOI: 10.1007/s40820-025-02063-x · Nano-Micro Letters · 2026-02-17

## TL;DR

This review explores how zinc-ion capacitors can be optimized for high energy and power density by analyzing two key device configurations and their electrolyte challenges.

## Contribution

The paper introduces a forward-looking roadmap for zinc-ion capacitors, including pulse voltage activation and high-entropy materials as electrodes.

## Key findings

- Zinc-ion capacitors (ZICs) are promising for high energy/power density and safety.
- Two configurations—ZC-ZICs and CB-ZICs—are analyzed for their energy storage mechanisms and electrolyte challenges.
- Solutions include pulse voltage activation and high-entropy materials for improved performance.

## Abstract

This review provides a comprehensive discussion of the energy storage mechanisms, electrode materials, and electrolyte-related challenges in two key configurations: zinc metal anode//capacitive cathode zinc-ion capacitors (ZC-ZICs) and capacitive anode//battery-type cathode ZICs (CB-ZICs).This review provides comprehensive and effective solutions to the core bottleneck issues in the two key configurations.This review proposes forward-looking development roadmap of the ZICs, including pulse voltage activation on carbon electrodes, application of high-entropy materials as electrodes, and the development of stable and multifunctional electrolytes.

This review provides a comprehensive discussion of the energy storage mechanisms, electrode materials, and electrolyte-related challenges in two key configurations: zinc metal anode//capacitive cathode zinc-ion capacitors (ZC-ZICs) and capacitive anode//battery-type cathode ZICs (CB-ZICs).

This review provides comprehensive and effective solutions to the core bottleneck issues in the two key configurations.

This review proposes forward-looking development roadmap of the ZICs, including pulse voltage activation on carbon electrodes, application of high-entropy materials as electrodes, and the development of stable and multifunctional electrolytes.

In response to the demanding requirements of next-generation energy storage systems for high-energy density, high-power density, and ultra-long-cycle life, the academic community has continued to focus on coupled devices that combine battery-level energy and capacitor-level power characteristics. Zinc-ion capacitors (ZICs) have become the most promising strategic candidate system for energy storage technology due to their high-energy/power characteristics, excellent intrinsic safety, and significant cost advantages. In this review, the latest research progress of ZICs is reviewed from the perspective of system. Firstly, ZICs are divided into zinc metal anode//capacitive cathode ZICs (ZC-ZICs) and capacitive anode//battery-type cathode ZICs (CB-ZICs) according to the device configuration, and the energy storage mechanisms are analyzed in depth. At the same time, focusing on the two configurations of ZC-ZICs and CB-ZICs and their electrolyte systems, problem-oriented the key puzzles and corresponding solutions are sorted out one by one. Finally, based on the above discussion, this review proposes forward-looking suggestions for material modifications of ZICs, including pulse voltage activation, application of high-entropy materials, and the development of stable and multi-functional electrolytes, aiming to provide scientific guidance for the practical application of high-performance ZICs and promote the in-depth development of high-performance ZICs research.

## Full-text entities

- **Genes:** UBE2K (ubiquitin conjugating enzyme E2 K) [NCBI Gene 3093] {aka E2-25K, HIP2, HYPG, LIG, UBC1}
- **Diseases:** NMS (MESH:D009459), TMCs (MESH:D005597), toxicity (MESH:D064420), MOFs (MESH:D013651)
- **Chemicals:** CO2 (MESH:D002245), BP (MESH:C038809), CMC (MESH:D002266), Co (MESH:D003035), polystyrene (MESH:D011137), CM (MESH:D003476), Bi2S3 (MESH:C049897), lignin (MESH:D008031), OH (MESH:C031356), KOH (MESH:C029943), bio-oil (MESH:C000613328), polypropylene (MESH:D011126), THF (MESH:C018674), sulfonic acid (MESH:D013451), alkali (MESH:D000468), LH- (MESH:D007986), LiCl (MESH:D018021), ZnSO4 (MESH:D019287), H (MESH:D006859), cellulose (MESH:D002482), MXene (MESH:C000723374), cyanide (MESH:D003486), VB (MESH:D025101), 1,4,7,10-tetraazacyclododecane (MESH:C038072), KCl (MESH:D011189), PM (MESH:D011399), halogen (MESH:D006219), VOSO4 (MESH:C034028), ice (MESH:D007053), oxides (MESH:D010087), argon (MESH:D001128), ZS (MESH:C000597310), Manganese (MESH:D008345), glucose (MESH:D005947), graphdiyne (MESH:C000657226), DMSO (MESH:D004121), MG (MESH:D008274), EE (MESH:D004997), S (MESH:D013455), graphene (MESH:D006108), H2O2 (MESH:D006861), COF-5 (-), K2CO3 (MESH:C037593), C-F (MESH:D002142), Fad (MESH:C031066), Na+ (MESH:D012964), BT (MESH:D001622), CB (MESH:C063451), SiO2 (MESH:D012822), K (MESH:D011188), ZnCl2 (MESH:C016837), carbon nanotube (MESH:D037742), urea (MESH:D014508), N-5 (MESH:C031785), tungsten oxide (MESH:C511604), thiol (MESH:D013438), PVA (MESH:D011142), Selenium (MESH:D012643), V2O5 (MESH:C066075), Cl- (MESH:D002713)
- **Species:** Homo sapiens (human, species) [taxon 9606]
- **Cell lines:** CNS-2 — Homo sapiens (Human), Crigler-Najjar syndrome, Induced pluripotent stem cell (CVCL_C014), HDPC-1 — Mus musculus (Mouse), Hybridoma (CVCL_C7RB)

## Full text

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## Figures

14 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12913889/full.md

## References

1 references — full list in the complete paper: https://tomesphere.com/paper/PMC12913889/full.md

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Source: https://tomesphere.com/paper/PMC12913889