Embedding Ru Clusters and Single Atoms into Perovskite Oxide Boosts Nitrogen Fixation and Affords Ultrahigh Ammonia Yield Rate

Zhiya Han; Diana Tranca; Fermín Rodríguez-Hernández; Kaiyue Jiang; Jichao Zhang; Mingyuan He; Fu Wang; Sheng Han; Peng Wu; Xiaodong Zhuang

doi:10.1002/smll.202208102

Embedding Ru Clusters and Single Atoms into Perovskite Oxide Boosts Nitrogen Fixation and Affords Ultrahigh Ammonia Yield Rate

Zhiya Han
, Diana Tranca
, Fermín Rodríguez-Hernández
, Kaiyue Jiang
, Jichao Zhang
, Mingyuan He
, Fu Wang^*
, Sheng Han^*
, Peng Wu^*
, Xiaodong Zhuang^*

^*此作品的通讯作者

化学与分子工程学院

East China Normal University
Shanghai Jiao Tong University
Universidad Autónoma de Madrid
CAS - Shanghai Advanced Research Institute
Shanghai Institute of Technology

科研成果: 期刊稿件 › 文章 › 同行评审

40 引用（Scopus）

摘要

Ammonia is a key chemical feedstock worldwide. Compared with the well-known Haber–Bosch method, electrocatalytic nitrogen reduction reaction (ENRR) can eventually consume less energy and have less CO₂ emission. In this study, a plasma-enhanced chemical vapor deposition method is used to anchor transition metal element onto 2D conductive material. Among all attempts, Ru single-atom and Ru-cluster-embedded perovskite oxide are discovered with promising electrocatalysis performance for ENRR (NH₃ yield rate of up to 137.5 ± 5.8 µg h⁻¹ mg_cat⁻¹ and Faradaic efficiency of unexpected 56.9 ± 4.1%), reaching the top record of Ru-based catalysts reported so far. In situ experiments and density functional theory calculations confirm that the existence of Ru clusters can regulate the electronic structure of Ru single atoms and decrease the energy barrier of the first hydrogenation step (*NN to *NNH). Anchoring Ru onto various 2D perovskite oxides (LaMO-Ru, M=Cr, Mn, Co, or Ni) also show boosted ENRR performance. Not only this study provides an unique strategy toward transition-metal-anchored new 2D conductive materials, but also paves the way for fundamental understanding the correlation between cluster-involved single-atom sites and catalytic performance.

源语言	英语
文章编号	2208102
期刊	Small
卷	19
期	17
DOI	https://doi.org/10.1002/smll.202208102
出版状态	已出版 - 26 4月 2023

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title = "Embedding Ru Clusters and Single Atoms into Perovskite Oxide Boosts Nitrogen Fixation and Affords Ultrahigh Ammonia Yield Rate",

abstract = "Ammonia is a key chemical feedstock worldwide. Compared with the well-known Haber–Bosch method, electrocatalytic nitrogen reduction reaction (ENRR) can eventually consume less energy and have less CO2 emission. In this study, a plasma-enhanced chemical vapor deposition method is used to anchor transition metal element onto 2D conductive material. Among all attempts, Ru single-atom and Ru-cluster-embedded perovskite oxide are discovered with promising electrocatalysis performance for ENRR (NH3 yield rate of up to 137.5 ± 5.8 µg h−1 mgcat−1 and Faradaic efficiency of unexpected 56.9 ± 4.1\%), reaching the top record of Ru-based catalysts reported so far. In situ experiments and density functional theory calculations confirm that the existence of Ru clusters can regulate the electronic structure of Ru single atoms and decrease the energy barrier of the first hydrogenation step (*NN to *NNH). Anchoring Ru onto various 2D perovskite oxides (LaMO-Ru, M=Cr, Mn, Co, or Ni) also show boosted ENRR performance. Not only this study provides an unique strategy toward transition-metal-anchored new 2D conductive materials, but also paves the way for fundamental understanding the correlation between cluster-involved single-atom sites and catalytic performance.",

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AU - Han, Zhiya

AU - Tranca, Diana

AU - Rodríguez-Hernández, Fermín

AU - Jiang, Kaiyue

AU - Zhang, Jichao

AU - He, Mingyuan

AU - Wang, Fu

AU - Han, Sheng

AU - Wu, Peng

AU - Zhuang, Xiaodong

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N2 - Ammonia is a key chemical feedstock worldwide. Compared with the well-known Haber–Bosch method, electrocatalytic nitrogen reduction reaction (ENRR) can eventually consume less energy and have less CO2 emission. In this study, a plasma-enhanced chemical vapor deposition method is used to anchor transition metal element onto 2D conductive material. Among all attempts, Ru single-atom and Ru-cluster-embedded perovskite oxide are discovered with promising electrocatalysis performance for ENRR (NH3 yield rate of up to 137.5 ± 5.8 µg h−1 mgcat−1 and Faradaic efficiency of unexpected 56.9 ± 4.1%), reaching the top record of Ru-based catalysts reported so far. In situ experiments and density functional theory calculations confirm that the existence of Ru clusters can regulate the electronic structure of Ru single atoms and decrease the energy barrier of the first hydrogenation step (*NN to *NNH). Anchoring Ru onto various 2D perovskite oxides (LaMO-Ru, M=Cr, Mn, Co, or Ni) also show boosted ENRR performance. Not only this study provides an unique strategy toward transition-metal-anchored new 2D conductive materials, but also paves the way for fundamental understanding the correlation between cluster-involved single-atom sites and catalytic performance.

AB - Ammonia is a key chemical feedstock worldwide. Compared with the well-known Haber–Bosch method, electrocatalytic nitrogen reduction reaction (ENRR) can eventually consume less energy and have less CO2 emission. In this study, a plasma-enhanced chemical vapor deposition method is used to anchor transition metal element onto 2D conductive material. Among all attempts, Ru single-atom and Ru-cluster-embedded perovskite oxide are discovered with promising electrocatalysis performance for ENRR (NH3 yield rate of up to 137.5 ± 5.8 µg h−1 mgcat−1 and Faradaic efficiency of unexpected 56.9 ± 4.1%), reaching the top record of Ru-based catalysts reported so far. In situ experiments and density functional theory calculations confirm that the existence of Ru clusters can regulate the electronic structure of Ru single atoms and decrease the energy barrier of the first hydrogenation step (*NN to *NNH). Anchoring Ru onto various 2D perovskite oxides (LaMO-Ru, M=Cr, Mn, Co, or Ni) also show boosted ENRR performance. Not only this study provides an unique strategy toward transition-metal-anchored new 2D conductive materials, but also paves the way for fundamental understanding the correlation between cluster-involved single-atom sites and catalytic performance.

KW - 2D

KW - nitrogen reduction reaction

KW - perovskite oxide

KW - ruthenium clusters

KW - single ruthenium atoms

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Embedding Ru Clusters and Single Atoms into Perovskite Oxide Boosts Nitrogen Fixation and Affords Ultrahigh Ammonia Yield Rate

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