来源：Electrochem 发布时间：2026/5/19 13:54:21

选择字号： 小 中 大

文献清单：2023-2025编辑精选文章 | MDPI Electrochem

期刊名：Electrochem

期刊主页：www.mdpi.com/journal/electrochem

本期编辑荐读为您精选了发表于Electrochem 关于电化学能源与传感领域的前沿研究，涵盖下一代储能技术、燃料电池关键材料与工程、电化学传感与检测以及电催化与基础电化学等，研究内容从能源材料创新延伸至高灵敏生物传感，从器件工程优化深入到基础理论探讨，呈现多学科交叉融合的研究格局。

1. A Review of Recent Advances in Multivalent Ion Batteries for Next Generation Energy Storage

下一代储能技术中多价离子电池最新进展综述

https://www.mdpi.com/2673-3293/6/4/44

Shah, R.; Marussich, K.; Mittal, V. A Review of Recent Advances in Multivalent Ion Batteries for Next Generation Energy Storage.Electrochem2025,6, 44.

2.Exploring DNA Nanostructures as Surface Engineering Techniques for Optimizing Nucleic Acid Biosensor Performance

探索DNA纳米结构作为表面工程技术在优化核酸生物传感器性能方面的应用

https://www.mdpi.com/2673-3293/6/4/40

Pyle, K.; Savrano?lu, N.; Avdan, S.N.; Ahmadi, S. Exploring DNA Nanostructures as Surface Engineering Techniques for Optimizing Nucleic Acid Biosensor Performance.Electrochem2025,6,40.

3.Water Management Strategies for Proton Exchange Membrane Fuel Cells: A Comprehensive Review

质子交换膜燃料电池水管理策略：综合综述

https://www.mdpi.com/2673-3293/6/4/38

Saeed, M.; El-Hameed, M.A.; Al-Hajri, E.; Kabbani, A. Water Management Strategies for Proton Exchange Membrane Fuel Cells: A Comprehensive Review.Electrochem2025,6, 38.

4. Charge Transfer Rates Controlled by Frequency Dispersion of Double-Layer Capacitances

电荷转移速率受双电层电容频率色散控制

https://www.mdpi.com/2673-3293/6/3/32

Aoki, K.J.; Chen, J. Charge Transfer Rates Controlled by Frequency Dispersion of Double-Layer Capacitances.Electrochem2025,6, 32.

5. Chemical Stability of PFSA Membranes in Heavy-Duty Fuel Cells: Fluoride Emission Rate Model

PFSA膜在重负荷燃料电池中的化学稳定性：氟化物排放率模型

https://www.mdpi.com/2673-3293/6/3/25

Johnson, L.R.; Wang, X.; Quesada, C.; Wang, X.; Mukundan, R.; Ahluwalia, R. Chemical Stability of PFSA Membranes in Heavy-Duty Fuel Cells: Fluoride Emission Rate Model.Electrochem2025,6, 25.

6. Electrochemical Etching vs. Electrochemical Deposition: A Comparative Bibliometric Analysis

电化学刻蚀与电化学沉积：一项比较性文献计量分析

https://www.mdpi.com/2673-3293/6/2/18

Suchikova, Y.; Nazarovets, S.; Popov, A.I. Electrochemical Etching vs. Electrochemical Deposition: A Comparative Bibliometric Analysis.Electrochem2025,6, 18.https://doi.org/10.3390/electrochem6020018

7. Recent Advancements in Na Super Ionic Conductor-Incorporated Composite Polymer Electrolytes for Sodium-Ion Battery Application

钠超离子导体复合聚合物电解质在钠离子电池应用中的最新究进展

https://www.mdpi.com/2673-3293/6/1/6

Senthilkumar, K.K.; Thiruvengadathan, R.; Raghava, R.B.T.S. Recent Advancements in Na Super Ionic Conductor-Incorporated Composite Polymer Electrolytes for Sodium-Ion Battery Application.Electrochem2025,6, 6.

8. Tape Casting of NASICON-Based Separators with High Conductivity for Na All-Solid-State Batteries

流延法制备高电导率NASICON基隔膜用于钠全固态电池

https://www.mdpi.com/2673-3293/6/1/5

Rosen, M.; Mahioui, S.; Schwab, C.; Dück, G.; Finsterbusch, M. Tape Casting of NASICON-Based Separators with High Conductivity for Na All-Solid-State Batteries.Electrochem2025,6, 5.

9. Electrochemical Sensing of Hydrogen Peroxide Using Composite Bismuth Oxide/Bismuth Oxyselenide Nanostructures: Antagonistic Influence of Tungsten Doping

利用复合氧化铋/硒化铋纳米结构进行过氧化氢电化学传感：钨掺杂的拮抗作用

https://www.mdpi.com/2673-3293/5/4/30

Walimbe, P.D.; Kumar, R.; Shringi, A.K.; Keelson, O.; Ouma, H.A.; Yan, F. Electrochemical Sensing of Hydrogen Peroxide Using Composite Bismuth Oxide/Bismuth Oxyselenide Nanostructures: Antagonistic Influence of Tungsten Doping.Electrochem2024,5, 455-469.

10. Low-Volume Electrochemical Sensor Platform for Direct Detection of Paraquat in Drinking Water

用于直接检测饮用水中百草枯的低容量电化学传感器平台

https://www.mdpi.com/2673-3293/5/3/22

Poudyal, D.C.; Samson, M.; Dhamu, V.N.; Mohammed, S.; Tanchez, C.N.; Puri, A.; Baby, D.; Muthukumar, S.; Prasad, S. Low-Volume Electrochemical Sensor Platform for Direct Detection of Paraquat in Drinking Water.Electrochem2024,5, 341-353.

11.Detection of Ovarian Cancer Biomarker Lysophosphatidic Acid Using a Label-Free Electrochemical Biosensor

利用无标记电化学生物传感器检测卵巢癌生物标志物溶血磷脂酸

https://www.mdpi.com/2673-3293/5/2/15

Ivanova, N.; Ahmadi, S.; Chan, E.; Fournier, L.; Spagnolo, S.; Thompson, M. Detection of Ovarian Cancer Biomarker Lysophosphatidic Acid Using a Label-Free Electrochemical Biosensor.Electrochem2024,5, 243-257.

12. High C-Rate Performant Electrospun LiFePO₄/Carbon Nanofiber Self-Standing Cathodes for Lithium-Ion Batteries

高倍率性能的静电纺丝LiFePO₄/碳纳米纤维自支撑正极用于锂离子电池

https://www.mdpi.com/2673-3293/5/2/14

Conti, D.M.; Urru, C.; Bruni, G.; Galinetto, P.; Albini, B.; Berbenni, V.; Capsoni, D. High C-Rate Performant Electrospun LiFePO₄/Carbon Nanofiber Self-Standing Cathodes for Lithium-Ion Batteries.Electrochem2024,5, 223-242.

13. The Electrocatalytic Oxygen Evolution Reaction Activity of Rationally Designed NiFe-Based Glycerates

合理设计的 NiFe 基甘油酸盐的电催化析氧反应活性

https://www.mdpi.com/2673-3293/5/1/5

Singh, V.K.; Malik, B.; Konar, R.; Avraham, E.S.; Nessim, G.D. The Electrocatalytic Oxygen Evolution Reaction Activity of Rationally Designed NiFe-Based Glycerates.Electrochem2024,5, 70-83.

14. Comparison of Different Electrochemical Methodologies for Electrode Reactions: A Case Study of Paracetamol

不同电化学方法在电极反应中的比较：以对乙酰氨基酚为例

https://www.mdpi.com/2673-3293/5/1/4

Masood, Z.; Muhammad, H.; Tahiri, I.A. Comparison of Different Electrochemical Methodologies for Electrode Reactions: A Case Study of Paracetamol.Electrochem2024,5, 57-69.

15. Use of Inner/Outer Sphere Terminology in Electrochemistry—A Hexacyanoferrate II/III Case Study

电化学中内/外球术语的使用——以六氰合铁(II/III)为例的案例研究

https://www.mdpi.com/2673-3293/4/3/22

Cassidy, J.F.; de Carvalho, R.C.; Betts, A.J. Use of Inner/Outer Sphere Terminology in Electrochemistry—A Hexacyanoferrate II/III Case Study.Electrochem2023,4, 313-349.

期刊介绍

主编：Masato Sone, Tokyo Institute of Technology, Japan

期刊Electrochem(ISSN 2673-3283) 创刊于2020年，最新CiteScore 7.4，在材料化学领域位于Q1，是一个国际性、经同行评审的开放获取英文学术期刊，研究范围涵盖与电化学研究相关的各个方面。期刊旨在为电化学及其应用研究提供一个先进的交流平台，鼓励科学家尽可能详细地发表他们的实验和理论成果。目前 Electrochem 已被Scopus、DOAJ、CAPlus/ SciFinder、EBSCO等多个重要数据库收录。

期刊领域包括但不限于：

对电化学原理和机制的探索；电化学材料及其应用；生物电化学、电化学分析与检测；能量转换与储存，如电化学能量转换与储存、光电化学电池；电化学表面科学等。

2024 CiteScore：7.4

Time to First Decision：20.7 Days

Acceptance to Publication：3.8 Days