In Situ X-Ray Techniques for Electrochemical Interfaces

被引:10
作者
Baggio, Bruna F. [1 ]
Grunder, Yvonne [1 ]
机构
[1] Univ Liverpool, Dept Phys, Oliver Lodge Lab, Liverpool L69 7ZE, England
来源
ANNUAL REVIEW OF ANALYTICAL CHEMISTRY, VOL 14, 2021 | 2021年 / 14卷
关键词
electrochemistry; surface X-ray diffraction; X-ray absorption; spectroscopy; CRYSTAL TRUNCATION ROD; SURFACE-STRUCTURE DETERMINATION; UNDERPOTENTIAL DEPOSITION; ION DISTRIBUTIONS; ABSORPTION SPECTROSCOPY; AU(001) RECONSTRUCTION; ELECTRODE SURFACES; AU(111) ELECTRODE; INITIAL-STAGES; SCATTERING;
D O I
10.1146/annurev-anchem-091020-100631
中图分类号
O65 [分析化学];
学科分类号
070302 ; 081704 ;
摘要
This article reviews progress in the study of materials using X-ray-based techniques from an electrochemistry perspective. We focus on in situ/in operando surface X-ray scattering, X-ray absorption spectroscopy, and the combination of both methods. The background of these techniques together with key concepts is introduced. Key examples of in situ and in operando investigation of liquid-solid and liquid-liquid interfaces are presented. X-ray scattering and spectroscopy have helped to develop an understanding of the underlying atomic and molecular processes associated with electrocatalysis, electrodeposition, and battery materials. We highlight recent developments, including resonant surface diffraction and time-resolved studies.
引用
收藏
页码:87 / 107
页数:21
相关论文
共 143 条
[1]   In Situ Dispersive EXAFS in Electrocatalysis: The Investigation of the Local Structure of IrOx in Chronoamperometric Conditions as a Case Study [J].
Achilli, Elisabetta ;
Minguzzi, Alessandro ;
Lugaresi, Ottavio ;
Locatelli, Cristina ;
Rondinini, Sandra ;
Spinolo, Giorgio ;
Ghigna, Paolo .
JOURNAL OF SPECTROSCOPY, 2014, 2014 :1-7
[2]   In-situ Spectroscopic Techniques as Critical Evaluation Tools for Electrochemical Carbon dioxide Reduction: A Mini Review [J].
Adarsh, K. S. ;
Chandrasekaran, Naveen ;
Chakrapani, Vidhya .
FRONTIERS IN CHEMISTRY, 2020, 8
[3]   INSITU SURFACE EXAFS AT CHEMICALLY MODIFIED ELECTRODES [J].
ALBARELLI, MJ ;
WHITE, JH ;
BOMMARITO, GM ;
MCMILLAN, M ;
ABRUNA, HD .
JOURNAL OF ELECTROANALYTICAL CHEMISTRY, 1988, 248 (01) :77-86
[4]   X-ray absorption spectroscopic studies on solid oxide fuel cells and proton -conducting ceramic fuel cells [J].
Amezawa, Koji .
CURRENT OPINION IN ELECTROCHEMISTRY, 2020, 21 :250-256
[5]  
[Anonymous], 2011, SURFACE ANAL PRINCIP
[6]  
[Anonymous], 2011, Elements of Modern X-ray Physics
[7]   Electrochemical CO2 Reduction: A Classification Problem [J].
Bagger, Alexander ;
Ju, Wen ;
Sofia Varela, Ana ;
Strasser, Peter ;
Rossmeisl, Jan .
CHEMPHYSCHEM, 2017, 18 (22) :3266-3273
[8]   In situ/operando synchrotron-based X-ray techniques for lithium-ion battery research [J].
Bak, Seong-Min ;
Shadike, Zulipiya ;
Lin, Ruoqian ;
Yu, Xiqian ;
Yang, Xiao-Qing .
NPG ASIA MATERIALS, 2018, 10 :563-580
[9]   Atomic Structure of Pt3Ni Nanoframe Electrocatalysts by in Situ X-ray Absorption Spectroscopy [J].
Becknell, Nigel ;
Kang, Yijin ;
Chen, Chen ;
Resasco, Joaquin ;
Kornienko, Nikolay ;
Guo, Jinghua ;
Markovic, Nenad M. ;
Somorjai, Gabor A. ;
Stamenkovic, Vojislav R. ;
Yang, Peidong .
JOURNAL OF THE AMERICAN CHEMICAL SOCIETY, 2015, 137 (50) :15817-15824
[10]   Rb+ Adsorption at the Quartz(101)-Aqueous Interface: Comparison of Resonant Anomalous X-ray Reflectivity with ab Initio Calculations [J].
Bellucci, Francesco ;
Lee, Sang Soo ;
Kubicki, James D. ;
Bandura, Andrei ;
Zhang, Zhan ;
Wesolowski, David J. ;
Fenter, Paul .
JOURNAL OF PHYSICAL CHEMISTRY C, 2015, 119 (09) :4778-4788
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