Unique Catalytic Mechanism for Ru-Loaded Ternary Intermetallic Electrides for Ammonia Synthesis

Gong, Yutong; Li, Hongchen; Wu, Jiazhen; Song, Xingyi; Yang, Xueqing; Bao, Xiaoguang; Han, Xiao; Kitano, Masaaki; Wang, Junjie; Hosono, Hideo

doi:10.1021/jacs.2c01899

Cited by 58 publications

(64 citation statements)

References 51 publications

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“…Because the mayenite framework is quite rigid, removing oxygen atoms from the cavities does not destroy it. Moreover, these cavities can embed, for example, ions of gold, platinum, and chlorine as well as rare-earth elements, leading to a wide variety of technological applications, including promising field-emission properties , and prominent catalytic activity. − Mayenite, which is self-doped with electrons placed in positively charged cavities, can exhibit interesting physical properties such as low work function, a state of phonon glass and an electron crystal state, a metal–insulator transition with a change in the concentration of interstitial electrons, and superconductivity. − These properties of mayenite originate from the nesting of electride electrons in the cages weakly coupled to the lattice. These electrons form the energy states lying in the vicinity of the Fermi level.…”

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confidence: 99%

Localization Mechanism of Interstitial Electronic States in Electride Mayenite

Novoselov

Mazannikova

Korotin

et al. 2022

J. Phys. Chem. Lett.

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confidence: 99%

Localization Mechanism of Interstitial Electronic States in Electride Mayenite

Novoselov

Mazannikova

Korotin

et al. 2022

J. Phys. Chem. Lett.

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“…Therefore, the presence of RE is indispensable for the outstanding supporting manner of ternary intermetallic electrides. Very recently, we found that the REs in the electrides are more than an electron donor [16,85]. La in LaTMSi (TM = Co, Fe, Ru, or Mn) is a better active site for the NH x formation and NH 3 desorption than the Ru site, which can help break the scaling relations on the Ru/LaTMSi catalysts.…”

Section: Re-based Electridesmentioning

confidence: 99%

“…Besides, they can alleviate or even avoid the H 2 poisoning effect, which is benefited from their strong H affinity that shunts H from Ru sites. Furthermore, the construction of the multi-sites (e.g., the Ru site or nitrogen-vacancy site for the N 2 activation [14,16], the Ni site for the H 2 activation [14], the RE site for the NH x formation [85]) would settle the competition of different elementary steps on one specific site. Recent studies have also revealed that the ammonia synthesis via an associative mechanism is preferable to the dissociative mechanism for a high-performance catalyst.…”

Section: Challenges and Outlookmentioning

confidence: 99%

“…Different from the traditional alkaline earth oxide supports, RE-involving supports, such as RE nitrides [14] and oxynitride-hydrides [15], can promise a more energy-favourable N 2 activation (Mars-van Krevelen mechanism), which dramatically decreases the energy barrier for the ammonia synthesis. In some cases, the REs act as a favourable active site for the combination of N and H [16]. The combination of the RE sites with the TM sites could liberate the ammonia synthesis from the scaling relations that trouble the conventional Ru and Fe materials, allowing the ammonia synthesis to proceed via a low-barrier path.…”

Section: Introduction mentioning

confidence: 99%

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Insight into rare-earth-incorporated catalysts: The chance for a more efficient ammonia synthesis

Gong

et al. 2022

J Adv Ceram

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Recent studies have suggested that rare earth (RE) elements in catalysts significantly influence the performance of the ammonia synthesis. The REs appear in various forms in the ammonia synthesis catalysts including supports (oxides, hydrides, and nitrides), promotors, and intermetallic. Besides the conventional RE oxide-supporting catalysts (mainly Ru/REO), some new RE-containing catalyst systems, such as electrode and nitride systems, could drive the ammonia synthesis via a benign Mars—van Krevelen mechanism or multi-active-site mode, affording high ammonia synthesis performance under mild conditions. These works demonstrate the great potential of RE-containing catalysts for more efficient ammonia synthesis. This review summarizes the contributions of different kinds of RE-based catalysts and highlights the function mechanism of incorporated REs. Finally, an overview of this area and the challenges for further investigation are provided.

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“…As shown in Figure 8, the calculated activation barriers for N 2 dissociation are 0.75 and 0.31 eV on Y 3 /G and Nb 3 /G, respectively, which are exothermic in total due to the large energy gain of N 2 adsorption, indicating that N 2 is prone to dissociate on such catalysts. 72 After nitrogen dissociation, the first hydrogenation step is to form N* + NH*; next, the two reaction pathways (distal and alternative) are considered as well. 37 In the alternative pathway, N* + NH* is hydrogenated to 2NH*, followed by alternate hydrogenation on two NH* to form 2NH 3 ultimately.…”

Section: Comprehensive Assessment Of Mmentioning

confidence: 99%

On the Nature of Three-Atom Metal Cluster Catalysis for N₂ Reduction to Ammonia

et al. 2022

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Catalytic N 2 activation and reduction for ammonia synthesis has been subject of intense research interest. Cluster-modified catalysts have been proposed as promising candidates for nitrogen activation due to the featured active sites and maximized synergistic effect. However, the nature of metal clusters itself has not been fully unveiled. Herein, we report a systematic investigation of N 2 activation and reduction on three-atom metal clusters (M 3 ) of all the 20 transition metals in the third and fourth periods of elements. We evaluate the catalysis of these M 3 clusters by taking into consideration three critical processes, namely, N 2 dissociation, hydrogenation, and NH 3 desorption. The TM I series of the M 3 clusters (Group 3B−5B metals) are found to support N 2 dissociation spontaneously, in contrast to the TM II and TM III clusters (i.e., Groups 6B−8B and 1B−2B). Based on the three criteria, Y 3 , Sc 3 , Zr 3 , and Nb 3 are identified as eligible candidates for ammonia synthesis. These clusters show preferable hollowsite N 2 adsorption and strong orbital hybridization, with electronic backdonation from the metal d orbitals to both π* and π/σ orbitals of N 2 . Further studies on ammonia synthesis have been conducted by applying Y 3 and Nb 3 clusters supported on graphene (Y 3 /G and Nb 3 /G), illustrating superior activity and potential application of such M 3 clusters. This work validates the three-atom cluster catalysis and guides the design of efficient catalysts for N 2 fixation.

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Unique Catalytic Mechanism for Ru-Loaded Ternary Intermetallic Electrides for Ammonia Synthesis

Cited by 58 publications

References 51 publications

Localization Mechanism of Interstitial Electronic States in Electride Mayenite

Localization Mechanism of Interstitial Electronic States in Electride Mayenite

Insight into rare-earth-incorporated catalysts: The chance for a more efficient ammonia synthesis

On the Nature of Three-Atom Metal Cluster Catalysis for N₂ Reduction to Ammonia

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Unique Catalytic Mechanism for Ru-Loaded Ternary Intermetallic Electrides for Ammonia Synthesis

Cited by 58 publications

References 51 publications

Localization Mechanism of Interstitial Electronic States in Electride Mayenite

Localization Mechanism of Interstitial Electronic States in Electride Mayenite

Insight into rare-earth-incorporated catalysts: The chance for a more efficient ammonia synthesis

On the Nature of Three-Atom Metal Cluster Catalysis for N2 Reduction to Ammonia

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On the Nature of Three-Atom Metal Cluster Catalysis for N₂ Reduction to Ammonia