Identification of Single-Atom Ni Site Active toward Electrochemical CO<sub>2</sub> Conversion to CO

Kim, Haesol; Shin, Dongyup; Yang, Woojin; Won, Da Hye; Oh, Hyung Suk; Chung, Min Wook; Jeong, Dae Hong; Kim, Sun Hee; Chae, Keun Hwa; Ryu, Ji Yeon; Lee, Ji Min; Cho, Sung June; Seo, Jiwon; Kim, Hyungjun; Choi, Chang Hyuck

doi:10.1021/jacs.0c11008

Cited by 122 publications

(82 citation statements)

References 52 publications

(111 reference statements)

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“…As a proof of concept, we chose to evaluate the catalytic performance of the UHD-SACs in the electrochemical CO 2 reduction to carbon monoxide, an application where nickel single atoms demonstrate promising technical potential 35,36 . For the Ni 1 /NC catalyst, the only products detected are gas-phase CO and H 2 and no liquids in the voltage range from 0 to -1.15 V versus RHE.…”

Section: Enhanced Productivity Of Uhd-sacsmentioning

confidence: 99%

Scalable two-step annealing method for preparing ultra-high-density single-atom catalyst libraries

et al. 2021

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The stabilization of transition metals as isolated centres on suitably tailored carriers with high density is crucial to exploit the technical potential of single-atom heterogeneous catalysts, enabling their maximized productivity in industrial reactors. Wet-chemical methods are best suited for practical applications due to their amenability to scale up. However, achieving single-atom dispersions at metal contents above 2 wt.% remains challenging. We introduce a versatile approach combining impregnation and two-step annealing to synthesize ultra-high-density single-atom catalysts (UHD-SACs) with unprecedented metal contents up to 23 wt.% for 15 metals on chemically-distinct carriers. Translation to an automated protocol demonstrates its robustness and provides a path to explore virtually unlimited libraries of mono or multimetallic catalysts. At the molecular level, characterization of the synthesis mechanism through experiments and simulations shows that controlling the bonding of metal precursors with the carrier via stepwise ligand removal prevents their thermally-induced aggregation into nanoparticles, ensuring atomic dispersion in the resulting UHD-SACs. The catalytic bene ts of UHD-SACs are demonstrated for the electrochemical reduction of CO 2 to CO over NiN 4 motifs on carbon.

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Section: Enhanced Productivity Of Uhd-sacsmentioning

confidence: 99%

Scalable two-step annealing method for preparing ultra-high-density single-atom catalyst libraries

et al. 2021

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“…In addition to metal phthalocyanines, some other molecular complexes, such as metal porphyrins, also have a defined M–N 4 structure. Kim et al reported carbon substrate supported Ni molecular complexes with two different porphyrins ligands, tetraphenylporphyrin (N 4 –TPP) and 21-oxatetraphenylporphyrin (N 3 O-TPP) 88 Spectroscopic and computational studies of Ni–N 4 -TPP and Ni(–Cl)–N 3 O-TPP revealed that the destruction of the ligand field symmetry could increase the redox potential from 0 to +1, leading to a better performance in the CO 2 RR. The additional ligand for the central atoms could also be a modification strategy to regulate the interfacial electronic structure from the axial direction.…”

Section: Design and Synthesis Of Sacs For The Co 2 Rrmentioning

confidence: 99%

The atomic-level regulation of single-atom site catalysts for the electrochemical CO₂ reduction reaction

Chen

et al. 2021

Chem. Sci.

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“…[ 4 ] The recent implementation of SACs into CO 2 reduction has proven that the microenvironments and electronic properties of single‐atom active centers are essential for catalytic activity. [ 5 ] Up to now, pioneering work have reported several strategies to modulate the local structure of single‐atom active sites and compare their catalytic performance on CO 2 conversion, such as designing molecular catalysts, [ 6 ] carbonization of functionalized precursors, [ 7 ] or tuning coordination number of metal centers supported on metal organic layers. [ 8 ] Despite of these developments, these methods either suffered from tedious synthetic process or indirectly controlled SACs configuration at atomic level.…”

Section: Introductionmentioning

confidence: 99%

Integrating Single Atoms with Different Microenvironments into One Porous Organic Polymer for Efficient Photocatalytic CO₂ Reduction

et al. 2021

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The precise identification of single‐atom catalysts (SACs) activity and boosting their efficiency toward CO2 conversion is imperative yet quite challenging. Herein, for the first time a series of porous organic polymers is designed and prepared simultaneously, containing well‐defined M–N4 and M–N2O2 single‐atom sites. Such a strategy not only offers multiactive sites to promote the catalytic efficiency but also provides a more direct chance to identify the metal center activity. The CO2 photoreduction results indicate that the introduction of salphen unit with Ni–N2O2 catalytic centers into pristine phthalocyanine‐based Ni–N4 framework achieves remarkable CO generation ability (7.77 mmol g–1) with a high selectivity of 96% over H2. In combination with control experiments, as well as theoretical studies, the Ni–N2O2 moiety is evidenced as a more active site for CO2RR compared with the traditional Ni–N4 moiety, which can be ascribed to the M–N2O2 active sites effectively reducing the energy barrier, facilitating the adsorption of reaction radicals *COOH, and improving the charge transportation. This work might shed some light on designing more efficient SACs toward CO2 reduction through modification of their coordination environments.

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Identification of Single-Atom Ni Site Active toward Electrochemical CO₂ Conversion to CO

Cited by 122 publications

References 52 publications

Scalable two-step annealing method for preparing ultra-high-density single-atom catalyst libraries

Scalable two-step annealing method for preparing ultra-high-density single-atom catalyst libraries

The atomic-level regulation of single-atom site catalysts for the electrochemical CO₂ reduction reaction

Integrating Single Atoms with Different Microenvironments into One Porous Organic Polymer for Efficient Photocatalytic CO₂ Reduction

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Identification of Single-Atom Ni Site Active toward Electrochemical CO2 Conversion to CO

Cited by 122 publications

References 52 publications

Scalable two-step annealing method for preparing ultra-high-density single-atom catalyst libraries

Scalable two-step annealing method for preparing ultra-high-density single-atom catalyst libraries

The atomic-level regulation of single-atom site catalysts for the electrochemical CO2 reduction reaction

Integrating Single Atoms with Different Microenvironments into One Porous Organic Polymer for Efficient Photocatalytic CO2 Reduction

Contact Info

Product

Resources

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Identification of Single-Atom Ni Site Active toward Electrochemical CO₂ Conversion to CO

The atomic-level regulation of single-atom site catalysts for the electrochemical CO₂ reduction reaction

Integrating Single Atoms with Different Microenvironments into One Porous Organic Polymer for Efficient Photocatalytic CO₂ Reduction