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1. Understanding the Origin of Highly Selective CO 2 Electroreduction to CO on Ni,N‐doped Carbon Catalysts

   https://doi.org/10.1002/ange.201912857  

   Koshy, David M. ; Chen, Shucheng ; Lee, Dong Un ; Stevens, Michaela Burke ; Abdellah, Ahmed M. ; Dull, Samuel M. ; Chen, Gan ; Nordlund, Dennis ; Gallo, Alessandro ; Hahn, Christopher ; et al ( January 2020 , Angewandte Chemie)

   Ni,N‐doped carbon catalysts have shown promising catalytic performance for CO₂electroreduction (CO₂R) to CO; this activity has often been attributed to the presence of nitrogen‐coordinated, single Ni atom active sites. However, experimentally confirming Ni−N bonding and correlating CO₂reduction (CO₂R) activity to these species has remained a fundamental challenge. We synthesized polyacrylonitrile‐derived Ni,N‐doped carbon electrocatalysts (Ni‐PACN) with a range of pyrolysis temperatures and Ni loadings and correlated their electrochemical activity with extensive physiochemical characterization to rigorously address the origin of activity in these materials. We found that the CO₂R to CO partial current density increased with increased Ni content before plateauing at 2 wt % which suggests a dispersed Ni active site. These dispersed active sites were investigated by hard and soft X‐ray spectroscopy, which revealed that pyrrolic nitrogen ligands selectively bind Ni atoms in a distorted square‐planar geometry that strongly resembles the active sites of molecular metal–porphyrin catalysts.

    

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2. Atomically dispersed single Ni site catalysts for high-efficiency CO 2 electroreduction at industrial-level current densities

   https://doi.org/10.1039/D2EE00318J  

   Li, Yi ; Adli, Nadia Mohd ; Shan, Weitao ; Wang, Maoyu ; Zachman, Michael J. ; Hwang, Sooyeon ; Tabassum, Hassina ; Karakalos, Stavros ; Feng, Zhenxing ; Wang, Guofeng ; et al ( May 2022 , Energy & Environmental Science)

   Atomically dispersed and nitrogen-coordinated single Ni sites ( i.e. , NiN x moieties) embedded in partially graphitized carbon have emerged as effective catalysts for CO 2 electroreduction to CO. However, much mystery remains behind the extrinsic and intrinsic factors that govern the overall catalytic CO 2 electrolysis performance. Here, we designed a high-performance single Ni site catalyst through elucidating the structural evolution of NiN x sites during thermal activation and other critical external factors ( e.g. , carbon particle sizes and Ni content) by using Ni–N–C model catalysts derived from nitrogen-doped carbon carbonized from a zeolitic imidazolate framework (ZIF)-8. The N coordination, metal–N bond length, and thermal wrinkling of carbon planes in Ni–N–C catalysts significantly depend on thermal temperatures. Density functional theory (DFT) calculations reveal that the shortening Ni–N bonds in compressively strained NiN 4 sites could intrinsically enhance the CO 2 RR activity and selectivity of the Ni–N–C catalyst. Notably, the NiN 3 active sites with optimal local structures formed at higher temperatures ( e.g. , 1200 °C) are intrinsically more active and CO selective than NiN 4 , providing a new opportunity to design a highly active catalyst via populating NiN 3 sites with increased density. We also studied how morphological factors such as the carbon host particle size and Ni loading alter the final catalyst structure and performance. The implementation of this catalyst in an industrial flow-cell electrolyzer demonstrated an impressive performance for CO generation, achieving a current density of CO up to 726 mA cm −2 with faradaic efficiency of CO above 90%, representing one of the best catalysts for CO 2 reduction to CO. 

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3. Direct Characterization of Atomically Dispersed Catalysts: Nitrogen‐Coordinated Ni Sites in Carbon‐Based Materials for CO 2 Electroreduction

   https://doi.org/10.1002/aenm.202001836  

   Koshy, David M. ; Landers, Alan T. ; Cullen, David A. ; Ievlev, Anton V. ; Meyer, III, Harry M. ; Hahn, Christopher ; Bao, Zhenan ; Jaramillo, Thomas F. ( September 2020 , Advanced Energy Materials)

   Metal, nitrogen‐doped carbon materials have attracted interest as heterogenous catalysts that contain MN_xactive sites that are analogous to molecular catalysts. Of particular interest is Ni,N‐doped carbon, a catalyst that is active for the electrochemical reduction of CO₂to CO. Critical to the understanding of these materials is proof of single atomic sites and characterization of the environment surrounding the metal atom; however, directly probing this coordination remains challenging. This challenge is addressed by combining scanning transmission electron microscopy (STEM), single atom electron energy loss spectroscopy (EELS), and time‐of‐flight secondary ion mass spectrometry (ToF‐SIMS). Through STEM imaging, atomic dispersion of Ni in the carbon framework is confirmed and image analyses are utilized to give semiquantitative estimates of neighbor distance distributions and site densities of Ni atoms. Atomic resolution EELS demonstrates that N and Ni are colocated at the single Ni atom sites suggesting Ni–N coordination. ToF‐SIMS reveals a distribution of NiN_xC_y⁻fragments that reflect the Ni–N bonding environments within Ni,N‐doped carbon. The fragmentation from Ni,N‐doped carbon is similar to Ni phthalocyanine, suggesting the existence of heterogenized, molecular‐like NiN₄active sites which motivates future studies that leverage insight from molecular catalysis design to develop next‐generation heterogeneous catalysts.

    

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4. Atomically Dispersed Single Ni Site Catalysts for Nitrogen Reduction toward Electrochemical Ammonia Synthesis Using N 2 and H 2 O

   https://doi.org/10.1002/smtd.201900821  

   Mukherjee, Shreya ; Yang, Xiaoxuan ; Shan, Weitao ; Samarakoon, Widitha ; Karakalos, Stavros ; Cullen, David A. ; More, Karren ; Wang, Maoyu ; Feng, Zhenxing ; Wang, Guofeng ; et al ( February 2020 , Small Methods)

   Ammonia (NH₃) electrosynthesis gains significant attention as NH₃is essentially important for fertilizer production and fuel utilization. However, electrochemical nitrogen reduction reaction (NRR) remains a great challenge because of low activity and poor selectivity. Herein, a new class of atomically dispersed Ni site electrocatalyst is reported, which exhibits the optimal NH₃yield of 115 µg cm⁻²h⁻¹at –0.8 V versus reversible hydrogen electrode (RHE) under neutral conditions. High faradic efficiency of 21 ± 1.9% is achieved at ‐0.2 V versus RHE under alkaline conditions, although the ammonia yield is lower. The Ni sites are stabilized with nitrogen, which is verified by advanced X‐ray absorption spectroscopy and electron microscopy. Density functional theory calculations provide insightful understanding on the possible structure of active sites, relevant reaction pathways, and confirm that the Ni‐N₃sites are responsible for the experimentally observed activity and selectivity. Extensive controls strongly suggest that the atomically dispersed NiN₃site‐rich catalyst provides more intrinsically active sites than those in N‐doped carbon, instead of possible environmental contamination. This work further indicates that single‐metal site catalysts with optimal nitrogen coordination is very promising for NRR and indeed improves the scaling relationship of transition metals.

    

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5. Designing and Engineering Atomically Dispersed Metal Catalysts for CO 2 to CO Conversion: From Single to Dual Metal Sites

   https://doi.org/10.1002/ange.202317884  

   Li, Yi ; Wang, Huanhuan ; Yang, Xiaoxuan ; O'Carroll, Thomas ; Wu, Gang ( January 2024 , Angewandte Chemie)

   The electrochemical CO₂reduction reaction (CO₂RR) is a promising approach to achieving sustainable electrical‐to‐chemical energy conversion and storage while decarbonizing the emission‐heavy industry. The carbon‐supported, nitrogen‐coordinated, and atomically dispersed metal sites are effective catalysts for CO generation due to their high activity, selectivity, and earth abundance. Here, we discuss progress, challenges, and opportunities for designing and engineering atomic metal catalysts from single to dual metal sites. Engineering single metal sites using a nitrogen‐doped carbon model was highlighted to exclusively study the effect of carbon particle sizes, metal contents, and M−N bond structures in the form of MN₄moieties on catalytic activity and selectivity. The structure‐property correlation was analyzed by combining experimental results with theoretical calculations to uncover the CO₂to CO conversion mechanisms. Furthermore, dual‐metal site catalysts, inheriting the merits of single‐metal sites, have emerged as a new frontier due to their potentially enhanced catalytic properties. Designing optimal dual metal site catalysts could offer additional sites to alter the surface adsorption to CO₂and various intermediates, thus breaking the scaling relationship limitation and activity‐stability trade‐off. The CO₂RR electrolysis in flow reactors was discussed to provide insights into the electrolyzer design with improved CO₂utilization, reaction kinetics, and mass transport.

    

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