Fundamental Drivers of Electrochemical Barriers

被引：6

作者：

Chen, Xi ^{[1
]}

Kastlunger, Georg ^{[2
]}

Peterson, Andrew A. ^{[1
]}

机构：

[1] Brown Univ, Sch Engn, Providence, RI 02912 USA

[2] Tech Univ Denmark, Dept Phys, DK-2800 Lyngby, Denmark

来源：

PHYSICAL REVIEW LETTERS | 2023年 / 131卷 / 23期

基金：

美国国家科学基金会;

关键词：

ELECTROLYTIC HYDROGEN EVOLUTION; BATTERY ELECTRIC VEHICLES; WORK FUNCTION; SCALING RELATIONS; OXYGEN REDUCTION; ADSORPTION; SIMULATION; KINETICS; ELEMENTS; DENSITY;

D O I：

10.1103/PhysRevLett.131.238003

中图分类号：

O4 [物理学];

学科分类号：

0702 ;

摘要：

We find that ion creation and destruction dominate the behavior of electrochemical reaction barriers, through grand-canonical electronic structure calculations of proton deposition on transition metal surfaces. We show that barriers respond to potential in a nonlinear manner and trace this to the continuous degree of electron transfer as an ion is created or destroyed. This explains both Marcus-like curvature and Hammond-like shifts. Across materials, we find the barrier energy to be driven primarily by the charge presented on the surface, which, in turn, is dictated by the native work function, a fundamentally different driving force than in nonelectrochemical systems.

引用

页数：7

共 50 条

[31] Nanoscale Hydrophobicity of Transport Barriers in the Nuclear Pore Complex as Compared with the Liquid/Liquid Interface by Scanning Electrochemical Microscopy
Huang, Siao-Han
Parandhaman, Moghitha
Ravi, Manu Jyothi
Janda, Donald C.
Amemiya, Shigeru
ANALYTICAL CHEMISTRY, 2025, 97 (05) : 2745 - 2753
[32] Electrochemical characteristics of molten iron electrodes in slag and electrochemical properties of their interface
Judge, W. D.
Paeng, J.
Azimi, G.
ELECTROCHIMICA ACTA, 2021, 389
[33] Understanding trends in the activity and selectivity of bi-atom catalysts for the electrochemical reduction of carbon dioxide†
Li, Fuhua
Tang, Qing
JOURNAL OF MATERIALS CHEMISTRY A, 2021, 9 (13) : 8761 - 8771
[34] Modelling competition of the enzyme-catalysed glucose oxidation and redox reactions in scanning electrochemical microscopy
Ciegis, Raimondas
Katauskis, Pranas
Skakauskas, Vladas
REACTION KINETICS MECHANISMS AND CATALYSIS, 2019, 127 (02) : 543 - 559
[35] Electrochemical immunoassay for CD10 antigen using scanning electrochemical microscopy
Song, Weiling
Yan, Zhiyong
Hu, Kongcheng
BIOSENSORS & BIOELECTRONICS, 2012, 38 (01) : 425 - 429
[36] Formation of vertically oriented graphenes: what are the key drivers of growth?
Baranov, O.
Levchenko, I.
Xu, S.
Lim, J. W. M.
Cvelbar, U.
Bazaka, K.
2D MATERIALS, 2018, 5 (04):
[37] Effect of the Random Defects Generated on the Surface of Pt(111) on the Electro-oxidation of Ethanol: An Electrochemical Study
Barbosa, Amaury F. B.
Del Colle, Vinicius
Gomez-Marin, Ana M.
Angelucci, Camilo A.
Tremiliosi-Filho, Germano
CHEMPHYSCHEM, 2019, 20 (22) : 3045 - 3055
[38] Insights into the Electrochemical Oxygen Evolution Reaction with ab Initio Calculations and Microkinetic Modeling: Beyond the Limiting Potential Volcano
Dickens, Colin F.
Kirk, Charlotte
Norskov, Jens K.
JOURNAL OF PHYSICAL CHEMISTRY C, 2019, 123 (31) : 18960 - 18977
[39] Microscopic understanding of the electrochemical interfaces
Sugino, Osamu
SOLAR CHEMICAL ENERGY STORAGE (SOLCHES), 2013, 1568 : 43 - 45
[40] Boundary Conditions for Electrochemical Interfaces
Landstorfer, Manuel
JOURNAL OF THE ELECTROCHEMICAL SOCIETY, 2017, 164 (11) : E3671 - E3685

← 1 2 3 4 5 →