V2O3/VN electrocatalysts with coherent heterogeneous interfaces for selecting low‐energy nitrogen reduction pathways
Tae‐Yong An,
Chengkai Xia,
Minyeong Je,
Hyunjung Lee,
Seulgi Ji,
Min‐Cheol Kim,
Subramani Surendran,
Mi‐Kyung Han,
Jaehyoung Lim,
Dong‐Kyu Lee,
Joon Young Kim,
Tae‐Hoon Kim,
Heechae Choi,
Jung Kyu Kim,
Uk Sim
Affiliations
Tae‐Yong An
Hydrogen Energy Technology Laboratory Korea Institute of Energy Technology (KENTECH) Naju Republic of Korea
Chengkai Xia
School of Chemical Engineering Sungkyunkwan University (SKKU) Suwon Republic of Korea
Minyeong Je
Materials & Chemistry Group, Institute of Inorganic Chemistry University of Cologne Cologne Germany
Hyunjung Lee
Hydrogen Energy Technology Laboratory Korea Institute of Energy Technology (KENTECH) Naju Republic of Korea
Seulgi Ji
Materials & Chemistry Group, Institute of Inorganic Chemistry University of Cologne Cologne Germany
Min‐Cheol Kim
School of Chemical Engineering Sungkyunkwan University (SKKU) Suwon Republic of Korea
Subramani Surendran
Hydrogen Energy Technology Laboratory Korea Institute of Energy Technology (KENTECH) Naju Republic of Korea
Mi‐Kyung Han
Department of Polymer Engineering, Graduate School, Alan G. MacDiarmid Energy Research Institute & School of Polymer Science and Engineering Chonnam National University Gwangju Republic of Korea
Jaehyoung Lim
Hydrogen Energy Technology Laboratory Korea Institute of Energy Technology (KENTECH) Naju Republic of Korea
Dong‐Kyu Lee
Hydrogen Energy Technology Laboratory Korea Institute of Energy Technology (KENTECH) Naju Republic of Korea
Joon Young Kim
Hydrogen Energy Technology Laboratory Korea Institute of Energy Technology (KENTECH) Naju Republic of Korea
Tae‐Hoon Kim
Department of Materials Science and Engineering Chonnam National University Gwangju Republic of Korea
Heechae Choi
Materials & Chemistry Group, Institute of Inorganic Chemistry University of Cologne Cologne Germany
Jung Kyu Kim
School of Chemical Engineering Sungkyunkwan University (SKKU) Suwon Republic of Korea
Uk Sim
Hydrogen Energy Technology Laboratory Korea Institute of Energy Technology (KENTECH) Naju Republic of Korea
Abstract Electrochemical nitrogen reduction reaction (NRR) is a sustainable alternative to the Haber‒Bosch process for ammonia (NH3) production. However, the significant uphill energy in the multistep NRR pathway is a bottleneck for favorable serial reactions. To overcome this challenge, we designed a vanadium oxide/nitride (V2O3/VN) hybrid electrocatalyst in which V2O3 and VN coexist coherently at the heterogeneous interface. Since single‐phase V2O3 and VN exhibit different surface catalytic kinetics for NRR, the V2O3/VN hybrid electrocatalyst can provide alternating reaction pathways, selecting a lower energy pathway for each material in the serial NRR pathway. As a result, the ammonia yield of the V2O3/VN hybrid electrocatalyst was 219.6 µg h−1 cm−2, and the Faradaic efficiency was 18.9%, which is much higher than that of single‐phase VN, V2O3, and VNxOy solid solution catalysts without heterointerfaces. Density functional theory calculations confirmed that the composition of these hybrid electrocatalysts allows NRR to proceed from a multistep reduction reaction to a low‐energy reaction pathway through the migration and adsorption of intermediate species. Therefore, the design of metal oxide/nitride hybrids with coherent heterointerfaces provides a novel strategy for synthesizing highly efficient electrochemical catalysts that induce steps favorable for the efficient low‐energy progression of NRR.
