Selective C−C Coupling by Spatially Confined Dimeric Metal Centers

Zhao, Yanyan; Zhao, Jijun; Zhao, Jijun

doi:10.1016/j.isci.2020.101051

Cited by 39 publications

(23 citation statements)

References 67 publications

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“…However, owing to the complexity of the CO 2 RR mechanism and the multifarious reaction products, more experimental and theoretical studies are required. TM 2 @phthalocyanine Mn 2 @phthalocyanine CH 3 OH −0.84 2017 [123] TM 2 @C 2 N Cu 2 @C 2 N CH 4 /C 2 H 4 −0.23 (CH 4 )/−0.76 (C 2 H 4 ) 2018 [124] Ni 2 , Co 2 , NiCo@C 2 N NiCo@C 2 N CH 4 −0.23 2019 [125] TM 1 /TM 2 @C 2 N CuCr/CuMn@C 2 N CH 4 −0.37/−0.32 2020 [50] TM 1 /TM 2 @N 6 -C CuMn, NiMn, NiFe@N 6 -C CO ≈−0.43 (CuMn); ≈−0.45 (NiFe); ≈−0.65 (NiMn) 2020 [52c] Fe 2 @holey N-doped carbon monolayers Fe 2 @C 2 N C 2 H 5 OH −0.70 2020 [126] Fen@graphdiyne (n = 1-4) Fe 2 @graphdiyne CH 4 −0.29 2020 [127] www.afm-journal.de www.advancedsciencenews.com…”

Section: (19 Of 25)mentioning

confidence: 99%

“More is Different:” Synergistic Effect and Structural Engineering in Double‐Atom Catalysts

Ying

Luo

Qiao

et al. 2020

Adv Funct Materials

194

149

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Double-atom catalysts (DACs) have emerged as a novel frontier in heterogeneous catalysis because the synergistic effect between adjacent active sites can promote their catalytic activity while maintaining high atomic utilization efficiency, good selectivity, and high stability originating from the atomically dispersed nature. In this review, the recent progress in both experimental and theoretical research on DACs for various catalytic reactions is focused. Specifically, the central tasks in the design of DACs-manipulating the synergistic effect and engineering atomic and electronic structures of catalysts-are systematically reviewed, along with the prevailing experimental, characterization, and computational modeling approaches. Furthermore, the practical applications of DACs in water splitting, oxygen reduction reaction, nitrogen reduction reaction, and carbon dioxide reduction reaction are addressed. Finally, the future challenges for DACs are summarized and an outlook on the further investigations of DACs toward heterogeneous catalysis in high-performance energy and environmental applications is provided.

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Section: (19 Of 25)mentioning

confidence: 99%

“More is Different:” Synergistic Effect and Structural Engineering in Double‐Atom Catalysts

Ying

Luo

Qiao

et al. 2020

Adv Funct Materials

194

149

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“…[ 52 ] The first‐principles calculations showed that the limiting two adjacent metal atoms in the vacancy of the carrier to form a synergetic active center can not only fix two CO 2 molecules at the same time, but also spatially limit the reaction path that is conducive to C–C coupling to form C2 or C2+ high‐valued chemical products. [ 159 ] Analogously, the synergistic effects by interactions of adjacent sites also apply to the before‐mentioned ultrahigh‐density SACs, [ 30,84 ] where their synergistic sites are highly dense and omnidirectional on support, thus leading to better catalytic properties in heterogeneous catalysis.…”

Section: Heterogeneous Catalysis Applications Of Afcsmentioning

confidence: 99%

Emerging Ultrahigh‐Density Single‐Atom Catalysts for Versatile Heterogeneous Catalysis Applications: Redefinition, Recent Progress, and Challenges

Liao

et al. 2022

Small Structures

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In recent years, single‐atom catalysts (SACs) with high metal loading have emerged in different heterogeneous catalysis fields and shown extraordinary catalytic properties. When there are enough coordination atoms (or functional groups) on the supports, it is possible to achieve a limit monolayer atom loading on the surface of supports with ultrahigh atom density (5–15 atoms nm−2) and extremely close site distance (0.2–0.5 nm), by using appropriate synthesis methods and procedures. These high‐density metal atoms usually have no or less metal bonds, which are mostly isolated by support atoms to form 3D foam‐like atomic constructions. Herein, a new notion of metal atomic foam catalysts (AFCs) is propsed to redefine these ultrahigh‐density SACs accommodated by specific supports. This new paradigm of 3D atomic construction for SACs has potential significance for both theoretical research and industrial applications. The latest major advancements in the controllable synthesis of AFCs on various supports (e.g., polymer, carbon, and metallic compound) via different methods (bottom‐up or top‐down approaches) are summarized. The latent catalytic principles and typical application cases of AFCs are emphasized in a wide range of heterogeneous catalysis fields (e.g., thermocatalysis, photocatalysis, electrocatalysis, etc.). The challenges and prospects of this newly 3D ultrahigh‐density AFCs materials in practical industrial application are pointed out as well.

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“…The electron accumulation and depletion regions are represented in different colors in Figure c. The charge transfer to CO 2 from the MBene surface and the electron transfer from transition metal to boron further contribute to the stability of the adsorption configurations. , For the M 3 B 4 -type MBene substrate, the favorable adsorption site is on top of the metal atom with adsorption energies of −0.06 eV, −0.25 eV, and −0.05 eV, corresponding to Nb 3 B 4 , Ta 3 B 4 , and V 3 B 4 , respectively. Furthermore, for Hf 2 B 2 and Zr 2 B 2 , the sites of boron also provide an energetically preferred adsorption energy for CO 2 reduction.…”

Section: Computational Methodsmentioning

confidence: 99%

Quantum Mechanical Screening of 2D MBenes for the Electroreduction of CO₂ to C1 Hydrocarbon Fuels

Xiao

Chen

Hadaeghi

2021

J. Phys. Chem. Lett.

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In this work, we propose a new family of two-dimensional (2D) transition metal borides (MBenes) to design and explore new high-efficiency catalysts for CO2 electroreduction according to the Density Functional Theory (DFT) approach. The recently reported MBenes have been synthesized experimentally and have been found to have high electrical conductivities and stability, so they are promising candidates for the development of CO2 electrocatalytic reduction (RR) catalysts. However, tuning the reaction mechanism such that the production of hydrocarbon species occurs at a low overpotential remains a challenge. Only C1 hydrocarbon products such as CH4, CH3OH, HCHO, CO, and HCOOH were identified, indicating that these MBenes have high stability, catalytic activity, and selectivity toward CO2 reduction and overcome the competing hydrogen evolution reaction (HER). These MBenes possess a metallic feature that can be tuned as a new catalyst for CO2RR, depending on the ability to control their selectivity and catalytic activity.

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Selective C−C Coupling by Spatially Confined Dimeric Metal Centers

Cited by 39 publications

References 67 publications

“More is Different:” Synergistic Effect and Structural Engineering in Double‐Atom Catalysts

“More is Different:” Synergistic Effect and Structural Engineering in Double‐Atom Catalysts

Emerging Ultrahigh‐Density Single‐Atom Catalysts for Versatile Heterogeneous Catalysis Applications: Redefinition, Recent Progress, and Challenges

Quantum Mechanical Screening of 2D MBenes for the Electroreduction of CO₂ to C1 Hydrocarbon Fuels

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Selective C−C Coupling by Spatially Confined Dimeric Metal Centers

Cited by 39 publications

References 67 publications

“More is Different:” Synergistic Effect and Structural Engineering in Double‐Atom Catalysts

“More is Different:” Synergistic Effect and Structural Engineering in Double‐Atom Catalysts

Emerging Ultrahigh‐Density Single‐Atom Catalysts for Versatile Heterogeneous Catalysis Applications: Redefinition, Recent Progress, and Challenges

Quantum Mechanical Screening of 2D MBenes for the Electroreduction of CO2 to C1 Hydrocarbon Fuels

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Product

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Quantum Mechanical Screening of 2D MBenes for the Electroreduction of CO₂ to C1 Hydrocarbon Fuels