目录 | 《电化学》2022年第3期(电化学前沿专辑-下)文章速览
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专辑介绍:《电化学》期刊2022年出版《电化学前沿专辑》(全英文),分为上、下两期,由复旦大学蔡文斌教授、厦门大学廖洪钢教授、中科院大连化物所彭章泉研究员共同担任客座编辑。
封面:北京师范大学毛兰群课题组致力于发展高选择性、生理兼容的电化学方法,在活体层次监测脑内神经分子的变化过程,揭示神经生理病理过程的分子机制。(文献号2108551)
本期收录8篇电化学研究领域各方向的综述和研究论文。扫描或识别二维码,免费查看、下载文献的PDF全文。
徐聪, 江迎, 于萍, 毛兰群. 脑神经电化学研究[J]. 电化学, 2022, 28(3): 2108551.
Cong Xu, Ying Jiang, Ping Yu, Lan-Qun Mao. Brain Electrochemistry[J]. Journal of Electrochemistry, 2022, 28(3): 2108551.
DOI: 10.13208/j.electrochem.210855
Brain, as the source of neural activities such as perceptions and emotions, consists of the dynamic and complex networks of neurons that implement brain functions through electrical and chemical interactions. Therefore, analyzing and monitoring neurochemicals in living brain can greatly contribute to uncovering the molecular mechanism in both physiological and pathological processes, and to taking a further step in developing precise medical diagnosis and treatment against brain diseases. Through collaborations across disciplines, a handful of analytical tools have been proven to be befitting in neurochemical measurement, spanning the level of vesicles, cells, and living brains. Among these, electrochemical methods endowed with high sensitivity and spatiotemporal resolution provide a promising way to precisely describe the dynamics of target neurochemicals during various neural activities. In this review, we expand the discussion on strategies to address two key issues of in vivo electrochemical sensing, namely, selectivity and biocompatibility, taking our latest studies as typical examples. We systematically elaborate for the first time the rationale behind engineering electrode/brain interface, as well as the unique advantages of potentiometric sensing methods. In particular, we highlight our recent progress on employing the as-prepared in vivo electrochemical sensors to unravel the molecular mechanism of ascorbate in physiological and pathological processes, aiming to draw a blueprint for the future development of in vivo electrochemical sensing of brain neurochemicals.
王越, 张立敏, 田阳. 基于电化学分子探针合理设计的高选择性长程活体分析[J]. 电化学, 2022, 28(3): 2108451.
Yue Wang, Li-Min Zhang, Yang Tian. Rational Design of Electrochemical Molecular Probes for Highly Selective and Long-Term Measurement In Vivo[J]. Journal of Electrochemistry, 2022, 28(3): 2108451.
DOI: 10.13208/j.electrochem.210845
Designing electrochemical interfaces for in vivo analysis of neurochemicals with high selectivity and long-term stability is vital for monitoring dynamic variation and dissecting the complex mechanisms of pathogenesis in living animals. This review focuses on the development of electrochemical interfaces based on rational design of molecular probes for in vivo measurement with high selectivity and high stability from three aspects: (1) Specific recognition probes were rationally designed and created to remarkably improve the selectivity of in vivo analysis in a complicated brain environment. (2) The Au-C≡C functionalized surface was developed to remarkably enhance the stability of molecular assembly, and employed for real-time mapping and accurate quantification in the brains. (3) Combined with the Au-C≡C functionalized molecular probe, the new type anti-biofouling microfiber array was established to achieve long-term and real-time monitoring dynamic changes in the brain. At last, some perspectives are highlighted in the further development of the efficient electrochemical interfaces for in vivo detection in the brain.
穆张岩, 丁梦宁. 电输运谱在原位电化学界面测量应用中的最新进展[J]. 电化学, 2022, 28(3): 2108491.
Zhang-Yan Mu, Meng-Ning Ding. Recent Advances in Electrical Transport Spectroscopy for the in Situ Measurement of Electrochemical Interfaces[J]. Journal of Electrochemistry, 2022, 28(3): 2108491.
DOI: 10.13208/j.electrochem.210849
Electrochemical/electrocatalytic technology has played a central role in achieving highly efficient energy conversion and storage. To date, the in-depth electrochemical research begins to require accurate and multi-dimensional information of electrochemical interfaces, which usually relies on the application of in situ characterizations. Electrical transport spectroscopy (ETS) is a newly developed measurement strategy based on chip-platform, and provides in situ information of electrochemical interfaces from a novel perspective due to a signal origin that is fundamentally different from typical spectroscopic and electrochemical techniques. In this tutorial review, the working principle and experimental setup of ETS are described in detail with the demonstration of several model electrocatalytic materials, including metal nanoparticle/nanowires, two-dimensional layered materials, nickel based hydroxide/oxyhydroxides and dissimilatory metal-reducing bacteria. The advantages of ETS are summarized, and the future challenges and opportunities that ETS faces are also prospected.
Jafar Hussain Shah, 谢起贤, 匡智崇, 格日乐, 周雯慧, 刘朵绒, Alexandre I. Rykov, 李旭宁, 罗景山, 王军虎. 原位57Fe穆斯堡尔光谱技术及其在Ni-Fe基析氧反应电催化剂中的应用[J]. 电化学, 2022, 28(3): 2108541.
Jafar Hussain Shah, Qi-Xian Xie, Zhi-Chong Kuang, Ri-Le Ge, Wen-Hui Zhou, Duo-Rong Liu, Alexandre I. Rykov, Xu-Ning Li, Jing-Shan Luo, Jun-Hu Wang. In-Situ/Operando57Fe Mössbauer Spectroscopic Technique and Its Applications in NiFe-based Electrocatalysts for Oxygen Evolution Reaction[J]. Journal of Electrochemistry, 2022, 28(3): 2108541.
DOI: 10.13208/j.electrochem.210854
The development of highly efficient and cost-effective electrocatalysts for the sluggish oxygen evolution reaction (OER) remains a significant barrier to establish effective utilization of renewable energy storage systems and water splitting to produce clean fuel. The current status of the research in developing OER catalysts shows that NiFe-based oxygen evolution catalysts (OECs) have been proven as excellent and remarkable candidates for this purpose. But it is critically important to understand the factors that influence their activity and underlying mechanism for the development of state-of-the-art OER catalysts. Therefore, the development of in-situ/operando characterizations is urgently required to detect key intermediates along with active sites and phases responsible for OER. 57Fe Mössbauer spectroscopy is one of the appropriate and suitable techniques for determining the phase structure of catalysts under their electrochemical working conditions, identifying the active sites, clarifying the catalytic mechanisms, and determining the relationship between catalytic activity and the coordination structure of catalysts. In this tutorial review, we have discussed the current status of research on NiFe-based catalysts with particular attention to introduce in detail the knowhow about the development and utilization of in-situ/operando57Fe Mössbauer-electrochemical spectroscopy for the study of OER mechanism. A brief overview using NiFe-(oxy)hydroxide catalysts, derived from ordered porous metal-organic framework (MOF) material NiFe-PBAs (Prussian blue analogues), as a typical model study case for the OER electrocatalyst and self-designed in-situ/operando57Fe Mössbauer-electrochemical instrument, has been provided for the better understanding of readers. Moreover, using in-situ/operando57Fe Mössbauer spectroscopy, the crucial role of Fe species during OER reaction has been explained very well.
宋亚杰, 孙雪, 任丽萍, 赵雷, 孔凡鹏, 王家钧. 同步辐射表征技术在金属空气电池研究中的应用[J]. 电化学, 2022, 28(3): 2108461.
Ya-Jie Song, Xue Sun, Li-Ping Ren, Lei Zhao, Fan-Peng Kong, Jia-Jun Wang. Synchrotron X-Rays Characterizations of Metal-Air Batteries[J]. Journal of Electrochemistry, 2022, 28(3): 2108461.
DOI: 10.13208/j.electrochem.210846
The rapid development of electric vehicles urgently requires high-energy-density batteries. Recently, metal-air batteries have attracted much attention in industry and academia for their ultra-high theoretical energy densities. However, the practical application of metal-air batteries is severely impeded by multiple drawbacks, including severe side reactions, low energy efficiency, and limited cycle life. Understanding the reaction mechanism of the cell and further developing effective strategies are beneficial for the practical application of metal-air batteries. In the past decade, advanced characterization techniques have accelerated the development of metal-air batteries. In particular, synchrotron radiation-based characterization techniques have been widely applied to the mechanistic study of metal-air batteries due to their non-destructive detection capability and high resolution. In this review, various synchrotron radiation-based characterization techniques are systematically summarized to understand the local structure and chemistry of metal-air batteries, with a special focus on how these advanced techniques can help understand the essence of degradation mechanism and optimization strategies. This progress report aims to highlight the crucial role of synchrotron radiation characterization for mechanism understanding of metal-air batteries.
冯雅辰, 王翔, 王宇琪, 严会娟, 王栋. 电催化氧还原反应的原位表征[J]. 电化学, 2022, 28(3): 2108531.
Ya-Chen Feng, Xiang Wang, Yu-Qi Wang, Hui-Juan Yan, Dong Wang. In Situ Characterization of Electrode Structure and Catalytic Processes in the Electrocatalytic Oxygen Reduction Reaction[J]. Journal of Electrochemistry, 2022, 28(3): 2108531.
DOI: 10.13208/j.electrochem.210853
As an electrochemical energy conversion system, fuel cell has the advantages of high energy conversion efficiency and high cleanliness. Oxygen reduction reaction (ORR), as an important cathode reaction in fuel cells, has received extensive attention. At present, the electrocatalysts are still one of the key materials restricting the further commercialization of fuel cells. The fundamental understanding on the catalytic mechanism of ORR is conducive to the development of electrocatalysts with the enhanced activity and high selectivity. This review aims to summarize the in situ characterization techniques used to study ORR. From this perspective, we first briefly introduce the advantages of various in situ techniques in ORR research, including electrochemical scanning tunneling microscopy, infrared spectroscopy, Raman spectroscopy, X-ray absorption spectroscopy, X-ray photoelectron spectroscopy and transmission electron microscopy. Then, the applications of various in situ characterization techniques in characterizing of the catalyst morphological evolution and electronic structure as well as the identification of reactants and intermediates in the catalytic process are summarized. Finally, the future development of in situ technology is outlooked.
陈梦洁, 芦思珉, 王浩炜, 龙亿涛. 单体电化学测量银纳米颗粒动态光解过程[J]. 电化学, 2022, 28(3): 2108521.
Mengjie Chen, Si-Min Lu, Hao-Wei Wang, Yi-Tao Long. Tracking Light-Induced Fragmentation of Single Silver Nanoparticles by Single Entity Electrochemistry[J]. Journal of Electrochemistry, 2022, 28(3): 2108521.
DOI: 10.13208/j.electrochem.210852
Light irradiation on silver nanoparticles (Ag NPs) could cause the energy conversion, thus, the fragmentation of Ag NPs. It is important to detect the changes of fragmented Ag NPs in the aspects of physical and chemical properties. Herein, benefiting from the high sensitivity, high temporal resolution, and high-throughput, single entity electrochemistry (SEE) method is introduced to in-situ track the dynamic laser fragmentation of single Ag NP. Compared with UV-Vis absorption spectroscopy and transmission electron microscopy (TEM), SEE methods enables an accurate in-situ measurements of light-induced fragmentation of single Ag NP. The variation in the statistic current amplitude displays the real-time changes of single Ag NP upon laser irradiation for 60 min, which indicates that the laser of 532 nm wavelength is the most effective laser for the dynamic fragmentation. By virtue of the excellent sensing performance, SEE is further applied in revealing the heterogeneity in Ag NPs’ intrinsic physicochemical properties, such as size, crystal structure, surface charge density. The study highlights the potential of SEE to advancing the real-time characterization of nanomaterials in the chemical reaction.
谢茂玲, 王钧, 胡晨吉, 郑磊, 孔华彬, 沈炎宾, 陈宏伟, 陈立桅. 基于非亲核电解液构建稳定的镁离子电池[J]. 电化学, 2022, 28(3): 2108561.
Mao-Ling Xie, Jun Wang, Chen-Ji Hu, Lei Zheng, Hua-Bin Kong, Yan-Bin Shen, Hong-Wei Chen, Li-Wei Chen. An Additive Incorporated Non-Nucleophilic Electrolyte for Stable Magnesium Ion Batteries[J]. Journal of Electrochemistry, 2022, 28(3): 2108561.
DOI: 10.13208/j.electrochem.210856
Non-nucleophilic electrolytes are promising next-generation highly stable electrolytes for magnesium-ion batteries (MIBs). However, a passivation layer on Mg metal anode usually blocks Mg2+ diffusion, leading to poor reaction kinetics and low Coulombic efficiency of the Mg plating/stripping in these electrolytes. Here we explore the utilization of phenyl disulfide (PDF) as a film-forming additive for non-nucleophilic electrolytes to regulate the interfacial chemistry on Mg metal anode. Phenyl-thiolate generated from the PDF additive was found to suppress the unfavorable surface blocking layer, resulted in a high Coulombic efficiency of up to 99.5% for the Mg plating/stripping process as well as a remarkably decreased overpotential. The full battery consisting of Mg metal anode and Mo6S7Se cathode remained stable in the PDF additive-containing electrolyte at 0.1 C over 150 cycles at room temperature.
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目录 | 《电化学》2022年第2期(电化学前沿专辑-上)文章速览
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《电化学》(Journal of Electrochemistry,简称J. Electrochem.)1995年由田昭武院士、查全性院士和吴浩青院士等创办,为中国化学会电化学专业委员会会刊,是中国第一个、也是唯一的融基础理论研究与技术应用为一体的电化学专业学术期刊,由中国科学技术协会主管、中国化学会和厦门大学共同主办,2022年变更为月刊,向国内外公开发行。《电化学》旨在及时反映我国电化学领域的最新科研成果和动态,促进国内、国际的学术交流。《电化学》遵循国际通行的办刊惯例,实行主编、副主编负责制,所有刊出稿件均必须经过同行评议。
《电化学》自创刊以来,已分别被北京大学图书馆、中国科学院和中国科技信息研究所遴选为“中国核心期刊”,被Scopus、CA、JST、CNKI、CSCD等国内外重要数据库收录,曾获《中国知识资源总库》精品期刊、华东地区优秀期刊等奖项。
竭诚欢迎广大学术界、产业界科技工作者踊跃投稿和订阅,为本刊献策建议。