Visualizing Eigen/Zundel cations and their interconversion in monolayer water on metal surfaces

Ye Tian; Jiani Hong; Duanyun Cao; Sifan You; Yizhi Song; Bowei Cheng; Zhichang Wang; Dong Guan; Xinmeng Liu; Zhengpu Zhao; Xin Zheng Li; Li Mei Xu; Jing Guo; Ji Chen; En Ge Wang; Ying Jiang

doi:10.1126/science.abo0823

Visualizing Eigen/Zundel cations and their interconversion in monolayer water on metal surfaces

Ye Tian, Jiani Hong, Duanyun Cao, Sifan You, Yizhi Song, Bowei Cheng, Zhichang Wang, Dong Guan, Xinmeng Liu, Zhengpu Zhao, Xin Zheng Li, Li Mei Xu, Jing Guo^*, Ji Chen^*, En Ge Wang^*, Ying Jiang^*

^*Corresponding author for this work

School of Material Science and Engineering

Research output: Contribution to journal › Article › peer-review

70 Citations (Scopus)

Abstract

The nature of hydrated proton on solid surfaces is of vital importance in electrochemistry, proton channels, and hydrogen fuel cells but remains unclear because of the lack of atomic-scale characterization. We directly visualized Eigen- and Zundel-type hydrated protons within the hydrogen bonding water network on Au(111) and Pt(111) surfaces, using cryogenic qPlus-based atomic force microscopy under ultrahigh vacuum. We found that the Eigen cations self-assembled into monolayer structures with local order, and the Zundel cations formed long-range ordered structures stabilized by nuclear quantum effects. Two Eigen cations could combine into one Zundel cation accompanied with a simultaneous proton transfer to the surface. Moreover, we revealed that the Zundel configuration was preferred over the Eigen on Pt(111), and such a preference was absent on Au(111).

Original language	English
Pages (from-to)	315-319
Number of pages	5
Journal	Science
Volume	377
Issue number	6603
DOIs	https://doi.org/10.1126/science.abo0823
Publication status	Published - 15 Jul 2022

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title = "Visualizing Eigen/Zundel cations and their interconversion in monolayer water on metal surfaces",

abstract = "The nature of hydrated proton on solid surfaces is of vital importance in electrochemistry, proton channels, and hydrogen fuel cells but remains unclear because of the lack of atomic-scale characterization. We directly visualized Eigen- and Zundel-type hydrated protons within the hydrogen bonding water network on Au(111) and Pt(111) surfaces, using cryogenic qPlus-based atomic force microscopy under ultrahigh vacuum. We found that the Eigen cations self-assembled into monolayer structures with local order, and the Zundel cations formed long-range ordered structures stabilized by nuclear quantum effects. Two Eigen cations could combine into one Zundel cation accompanied with a simultaneous proton transfer to the surface. Moreover, we revealed that the Zundel configuration was preferred over the Eigen on Pt(111), and such a preference was absent on Au(111).",

author = "Ye Tian and Jiani Hong and Duanyun Cao and Sifan You and Yizhi Song and Bowei Cheng and Zhichang Wang and Dong Guan and Xinmeng Liu and Zhengpu Zhao and Li, {Xin Zheng} and Xu, {Li Mei} and Jing Guo and Ji Chen and Wang, {En Ge} and Ying Jiang",

year = "2022",

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day = "15",

doi = "10.1126/science.abo0823",

language = "English",

volume = "377",

pages = "315--319",

journal = "Science",

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TY - JOUR

T1 - Visualizing Eigen/Zundel cations and their interconversion in monolayer water on metal surfaces

AU - Tian, Ye

AU - Hong, Jiani

AU - Cao, Duanyun

AU - You, Sifan

AU - Song, Yizhi

AU - Cheng, Bowei

AU - Wang, Zhichang

AU - Guan, Dong

AU - Liu, Xinmeng

AU - Zhao, Zhengpu

AU - Li, Xin Zheng

AU - Xu, Li Mei

AU - Guo, Jing

AU - Chen, Ji

AU - Wang, En Ge

AU - Jiang, Ying

PY - 2022/7/15

Y1 - 2022/7/15

N2 - The nature of hydrated proton on solid surfaces is of vital importance in electrochemistry, proton channels, and hydrogen fuel cells but remains unclear because of the lack of atomic-scale characterization. We directly visualized Eigen- and Zundel-type hydrated protons within the hydrogen bonding water network on Au(111) and Pt(111) surfaces, using cryogenic qPlus-based atomic force microscopy under ultrahigh vacuum. We found that the Eigen cations self-assembled into monolayer structures with local order, and the Zundel cations formed long-range ordered structures stabilized by nuclear quantum effects. Two Eigen cations could combine into one Zundel cation accompanied with a simultaneous proton transfer to the surface. Moreover, we revealed that the Zundel configuration was preferred over the Eigen on Pt(111), and such a preference was absent on Au(111).

AB - The nature of hydrated proton on solid surfaces is of vital importance in electrochemistry, proton channels, and hydrogen fuel cells but remains unclear because of the lack of atomic-scale characterization. We directly visualized Eigen- and Zundel-type hydrated protons within the hydrogen bonding water network on Au(111) and Pt(111) surfaces, using cryogenic qPlus-based atomic force microscopy under ultrahigh vacuum. We found that the Eigen cations self-assembled into monolayer structures with local order, and the Zundel cations formed long-range ordered structures stabilized by nuclear quantum effects. Two Eigen cations could combine into one Zundel cation accompanied with a simultaneous proton transfer to the surface. Moreover, we revealed that the Zundel configuration was preferred over the Eigen on Pt(111), and such a preference was absent on Au(111).

UR - http://www.scopus.com/inward/record.url?scp=85134317308&partnerID=8YFLogxK

U2 - 10.1126/science.abo0823

DO - 10.1126/science.abo0823

M3 - Article

C2 - 35857595

AN - SCOPUS:85134317308

SN - 0036-8075

VL - 377

SP - 315

EP - 319

JO - Science

JF - Science

IS - 6603

ER -

Visualizing Eigen/Zundel cations and their interconversion in monolayer water on metal surfaces

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