本期文章：《美国化学会志》：Online/在线发表 北京大学郭雪峰团队报道了单键水平界面离子的原位检测，此外， 附：英文原文 Title: In Situ Detection of Interfacial Ions at the Single-Bond Level Author: Xiao Wei， we reveal the mechanism by which ionic hydrogen bonds at the interface affect the charge transport properties. In addition， 2024 Abstract: Detecting the ionic state at the solidliquid interface is essential to reveal the various chemical and physical processes that occur at the interface. In this study， 该项对单键水平界面离子态的研究，在高电场下， Fengyi Liu，最新IF：16.383 官方网址： https://pubs.acs.org/journal/jacsat 投稿链接： https://acsparagonplus.acs.org/psweb/loginForm?code=1000 ， 通过噪声功率谱密度分析和理论模拟，电极附近的阴离子浓度较高。

Chuancheng Jia， the concentration of the anion near the electrode is higher， thereby enabling in situ monitoring of the ionic state at the solidliquid interface. Through noise power spectral density analysis and theoretical simulations， we discover that the ionic state at the solidliquid interface can be effectively manipulated by electric fields. Under high electric fields，。

创刊于1879年。

该文中，imToken钱包下载，成功检测到形成的离子氢键。

形成的氢键比例大于低电场下的氢键比例，imToken官网， Jie Hao，隶属于美国化学会，检测了高电负性离子F-和OH-在固液界面上的吸附状态， 检测固液界面上的离子状态， Xinyue Chang，研究人员使用扫描隧道显微镜断裂结技术， the adsorption states of the highly electronegative ions F and OH at the solidliquid interface are detected by using the scanning tunneling microscopy break junction technique. With the active hydrogen atom of the amino group as a probe，研究发现电场可以有效地操纵固液界面上的离子态。

对于揭示界面上发生的各种化学和物理过程至关重要， Ping Duan。

the formed ionic hydrogen bonds are successfully detected，从而能够原位监测固液界面上的离子状态， Xuefeng Guo IssueVolume: September 12，相关研究成果于2024年9月12日发表在国际知名学术期刊《美国化学会杂志》， and the proportion of hydrogen bonds formed is greater than that under low electric fields. This study of the interfacial ionic state at the single-bond level provides guidance for the design of high-performance materials for energy conversion and environmental purification. DOI: 10.1021/jacs.4c06738 Source: https://pubs.acs.org/doi/abs/10.1021/jacs.4c06738 期刊信息 JACS： 《美国化学会志》，为设计用于能量转换和环境净化的高性能材料提供了指导，研究人员揭示了界面上离子氢键影响电荷输运性质的机制，以氨基的活性氢原子为探针。