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1. Dissecting Critical Factors for Electrochemical CO 2 Reduction on Atomically Precise Au Nanoclusters

   https://doi.org/10.1002/anie.202211771  

   Li, Site ; Nagarajan, Anantha Venkataraman ; Du, Xiangsha ; Li, Yingwei ; Liu, Zhongyu ; Kauffman, Douglas R. ; Mpourmpakis, Giannis ; Jin, Rongchao ( October 2022 , Angewandte Chemie International Edition)

   This work investigates the critical factors impacting electrochemical CO₂reduction reaction (CO₂RR) using atomically precise Au nanoclusters (NCs) as electrocatalysts. First, the influence of size on CO₂RR is studied by precisely controlling NC size in the 1–2.5 nm regime. We find that the electrocatalytic CO partial current density increases for smaller NCs, but the CO Faradaic efficiency (FE) is not directly associated with the NC size. This indicates that the surface‐to‐volume ratio, i.e. the population of active sites, is the dominant factor for determining the catalytic activity, but the selectivity is not directly impacted by size. Second, we compare the CO₂RR performance of Au₃₈isomers (Au₃₈Q and Au₃₈T) to reveal that structural rearrangement of identical size NCs can lead to significant changes in both CO₂RR activity and selectivity. Au₃₈Q shows higher activity and selectivity towards CO than Au₃₈T, and density functional theory (DFT) calculations reveal that the average formation energy of the key *COOH intermediate on the proposed active sites is significantly lower on Au₃₈Q than Au₃₈T. These results demonstrate how the structural isomerism can impact stabilization of reaction intermediates as well as the overall CO₂RR performance of identical size Au NCs. Overall, this work provides important structure–property relationships for tailoring the NCs for CO₂RR.

    

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2. Boosting Activity and Selectivity of CO 2 Electroreduction by Pre‐Hydridizing Pd Nanocubes

   https://doi.org/10.1002/smll.202005305  

   Chang, Qiaowan ; Kim, Jeonghyeon ; Lee, Ji Hoon ; Kattel, Shyam ; Chen, Jingguang G. ; Choi, Sang‐Il ; Chen, Zheng ( November 2020 , Small)

   The electrochemical CO₂reduction reaction (CO₂RR) to syngas represents a promising solution to mitigate CO₂emissions and manufacture value‐added chemicals. Palladium (Pd) has been identified as a potential candidate for syngas production via CO₂RR due to its transformation to Pd hydride under CO₂RR conditions, however, the pre‐hydridized effect on the catalytic properties of Pd‐based electrocatalysts has not been investigated. Herein, pre‐hydridized Pd nanocubes (PdH_0.40) supported on carbon black (PdH_0.40NCs/C) are directly prepared from a chemical reduction method. Compared with Pd nanocubes (Pd NCs/C), PdH_0.40NCs/C presented an enhanced CO₂RR performance due to its less cathodic phase transformation revealed by the in situ X‐ray absorption spectroscopy. Density functional theory calculations revealed different binding energies of key reaction intermediates on PdH_0.40NCs/C and Pd NCs/C. Study of the size effect further suggests that NCs of smaller sizes show higher activity due to their more abundant active sites (edge and corner sites) for CO₂RR. The pre‐hydridization and reduced NC size together lead to significantly improved activity and selectivity of CO₂RR.

    

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3. Elucidating the active sites for CO 2 electroreduction on ligand-protected Au 25 nanoclusters

   https://doi.org/10.1039/c8cy01099d  

   Austin, Natalie ; Zhao, Shuo ; McKone, James R. ; Jin, Rongchao ; Mpourmpakis, Giannis ( January 2018 , Catalysis Science & Technology)

   Using density functional theory (DFT) calculations, we investigated the electrochemical reduction of CO 2 and the competing H 2 evolution reaction on ligand-protected Au 25 nanoclusters (NCs) of different charge states, Au 25 (SR) 18 q ( q = −1, 0, +1). Our results showed that regardless of charge state, CO 2 electroreduction over Au 25 (SR) 18 q NCs was not feasible because of the extreme endothermicity to stabilize the carboxyl (COOH) intermediate. When we accounted for the removal of a ligand (both –SR and –R) from Au 25 (SR) 18 q under electrochemical conditions, surprisingly we found that this is a thermodynamically feasible process at the experimentally applied potentials with the generated surface sites becoming active centers for electrocatalysis. In every case, the negatively charged NCs, losing a ligand from their surface during electrochemical conditions, were found to significantly stabilize the COOH intermediate, resulting in dramatically enhanced CO 2 reduction. The generated sites for CO 2 reduction were also found to be active for H 2 evolution, which agrees with experimental observations that these two processes compete. Interestingly, we found that the removal of an –R ligand from the negatively charged NC, resulted in a catalyst that was both active and selective for CO 2 reduction. This work highlights the importance of both the overall charge state and generation of catalytically active surface sites on ligand-protected NCs, while elucidating the CO 2 electroreduction mechanisms. Overall, our work rationalizes a series of experimental observations and demonstrates pathways to convert a very stable and catalytically inactive NC to an active electrocatalyst. 

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4. 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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5. Effect of surface ligands on gold nanocatalysts for CO 2 reduction

   https://doi.org/10.1039/d0sc05089j  

   Shang, Hongyu ; Wallentine, Spencer K. ; Hofmann, Daniel M. ; Zhu, Quansong ; Murphy, Catherine J. ; Baker, L. Robert ( January 2020 , Chemical Science)

   null (Ed.)

   Nanoparticle catalysts display optimal mass activity due to their high surface to volume ratio and tunable size and structure. However, control of nanoparticle size requires the presence of surface ligands, which significantly influence catalytic performance. In this work, we investigate the effect of dodecanethiol on the activity, selectivity, and stability of Au nanoparticles for electrochemical carbon dioxide reduction (CO 2 R). Results show that dodecanethiol on Au nanoparticles significantly enhances selectivity and stability with minimal loss in activity by acting as a CO 2 -permeable membrane, which blocks the deposition of metal ions that are otherwise responsible for rapid deactivation. Although dodecanethiol occupies 90% or more of the electrochemical active surface area, it has a negligible effect on the partial current density to CO, indicating that it specifically does not block the active sites responsible for CO 2 R. Further, by preventing trace ion deposition, dodecanethiol stabilizes CO production on Au nanoparticles under conditions where CO 2 R selectivity on polycrystalline Au rapidly decays to zero. Comparison with other surface ligands and nanoparticles shows that this effect is specific to both the chemical identity and the surface structure of the dodecanethiol monolayer. To demonstrate the potential of this catalyst, CO 2 R was performed in electrolyte prepared from ambient river water, and dodecanethiol-capped Au nanoparticles produce more than 100 times higher CO yield compared to clean polycrystalline Au at identical potential and similar current. 

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