Confined Ru Nanocatalysts on Surface to Enhance Ammonia Synthesis: An In situ ETEM Study

Ding, Jia; Wang, Lizhuo; Wu, Ping; Li, Ang; Li, Wei; Stampfl, Catherine; Liao, Xiaozhou; Haynes, Brian S.; Han, Xiaodong; Huang, Jun

doi:10.1002/cctc.202001423

Cited by 11 publications

(9 citation statements)

References 69 publications

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“…These results demonstrate that the tuning of the anion of the support has a significant influence on NH 3 synthesis performance. Previous studies have demonstrated that the activity of Ru-based catalysts without a promoter is negligible, and the introduction of a proper promoter to the Ru-based catalyst would enhance NH 3 synthesis. , Herein, different promoters, such as K, Ba, and Cs, were introduced into best-performing Ru/ZrH 2 . Among them, Ba exhibits an optimal promoting effect, and the NH 3 synthesis rate over Ba–Ru/ZrH 2 (5 wt % Ba) can reach up to 27.5 mmol g –1 h –1 , which is 3.1 times that of Ru/ZrH 2 (Figures a and S2).…”

Section: Resultsmentioning

confidence: 99%

Essential Role of Ru–Anion Interaction in Ru-Based Ammonia Synthesis Catalysts

et al. 2022

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The metal–anion interaction (MAI) widely exists over supported metal catalysts, which has a significant effect on tuning metal sites and reaction performance. However, the effect of MAI on NH3 synthesis and the reaction mechanism is still elusive. Here, we report that the strength of Ru–anion interaction gradually increases from Ru–N to Ru–H and Ru–O when the anion of the support is changed from H (ZrH2) to N (ZrN) and O (ZrO2). Moreover, the Ru–anion interaction induced by different support compositions can affect the hydrogen spillover and N2 activation route. Due to the weak Ru–N interaction, the aggregation of Ru particles is observed over Ru/ZrN. Although Ru particles are highly dispersed over ZrO2 owing to the strong Ru–O interaction, hydrogen poisoning is inevitable over Ru/ZrO2. Comparatively, hydrogen poisoning can be alleviated over Ru/ZrH2 via hydrogen spillover to its support. The results of NEXAFS, in situ diffuse reflectance infrared Fourier transform spectroscopy (DRIFTS), and isotope-labeling experiments show that N2 can be activated via both dissociative and associative routes over Ru/ZrH2. Consequently, the developed Ba-promoted Ru/ZrH2 catalyst displays a high NH3 synthesis rate of 27.5 mmol g–1 h–1 and robust stability during 300 h time-on-stream at 400 °C and 1 MPa.

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Section: Resultsmentioning

confidence: 99%

Essential Role of Ru–Anion Interaction in Ru-Based Ammonia Synthesis Catalysts

et al. 2022

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“…It could be suggested that the dissociative route of NH 3 synthesis is preferred over the Ru sites, consistent with previous studies. 18,19 Moreover, in the case of the reaction over the nitrogen vacancy of TiCN (Figures 5b and S22b), the N 2 adsorbed on the vacancy is more activated and the N−N bond distance is much longer (1.46 Å) due to the electrons captured in the vacancy. Therefore, as electrons transfer from the adjacent Ti and Ru atoms (Figure S23b), the Bader charge of the absorbed N 2 (−2.48|e|) is more negative than for Ru active sites and the π*-N 2 orbitals are more stabilized with obvious interaction with TiCN below the Fermi level (Figure S24).…”

Section: Identification Of the Dissociative Mechanismmentioning

confidence: 99%

“…Nevertheless, the activation of N 2 largely relies on the availability of nitride vacancy formation, and NH 3 is only generated on metal nitride, which in some degree constrains the catalytic performance. On the other hand, Ru-based catalysts as the second-generation catalysts for ammonia synthesis are capable of facile dissociation of the NN triple bond on Ru B 5 -stepped sites via a dissociative route. , Taking advantage of the metal nitride and Ru metal for N 2 activation, we envisage that a Ru-based catalyst promoted by an appropriate titanium carbonitride (TiCN) (TiC 0.5 N 0.5 , denoted as TiCN) might result in active sites for N 2 activation via both dissociative and associative routes, a strategy for NH 3 synthesis that has not been reported before. It is pivotal to determine the simultaneous occurrence of the two routes and to clarify whether the synergistic mechanism enhances the catalytic performance under mild conditions.…”

Section: Introductionmentioning

confidence: 99%

Integrating Dissociative and Associative Routes for Efficient Ammonia Synthesis over a TiCN-Promoted Ru-Based Catalyst

Zhou

Tan

et al. 2022

ACS Catal.

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Dinitrogen activation in ammonia (NH 3 ) synthesis usually obeys either the dissociative or associative route. We report here a combination of dissociative and associative routes over a titanium carbonitride (TiCN)-promoted Ru-based catalyst to achieve an outstanding NH 3 synthesis rate. The developed Ru/3TiCN/ZrH 2 catalyst shows a superior NH 3 synthesis rate of 25.6 mmol g cat −1 h −1 at 400 °C and 1 MPa. Our studies reveal that TiCN transfers electrons to the Ru centers and reduces the aggregation of Ru metal particles to generate more B 5 sites, thus accelerating the dissociation of N 2 to form NH 3 via a dissociative route. Meanwhile, the facile formation of nitrogen vacancies on TiCN assisted by Ru enables the associative mechanism initiated with N 2 hydrogenation to form *NNH. The synergistic effect of Ru and TiCN on N 2 activation via integrating the dissociative and associative mechanisms accounts for the superior NH 3 synthesis rate of our catalyst under mild conditions.

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“…However, the methanation of carbon supports during the reaction leads to the metal sintering and then the loss of active B5 sites . As shown in Figure b, it is found that the Ru atoms on the edges and steps of Ru NPs could be stabilized by MgO modification under high temperatures, which remained active B5 sites for ammonia synthesis . Moreover, the further incorporation of CsO x promoted the electron donation and then enhance the ammonia synthesis rate, which is 5-fold higher than MgO-Ru/MS.…”

Section: Ammonia Synthesis Over Ru-based Catalystsmentioning

confidence: 99%

Challenges and Opportunities of Ru-Based Catalysts toward the Synthesis and Utilization of Ammonia

et al. 2022

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Ammonia is an important chemical for synthesized fertilizers traditionally and for a potential energy vector increasingly. Industrial ammonia synthesis through the Haber–Bosch process is energy-intensive and requires advanced materials to catalyze ammonia synthesis under mild conditions, whereas the utilization of ammonia as a hydrogen carrier via ammonia decomposition is facing a similar situation as well. The developed second-generation Ru-based catalysts performs superior activities over commercial Fe- or Ni-based catalysts; however, it remains challenging to construct effective Ru catalysts to achieve the usage of Ru metal affordably as well as further understanding the nature of Ru catalysis. This Perspective summarizes the recent contributions in engineering Ru-based catalysts via various strategies and related catalysis in ammonia synthesis and decomposition, and it discusses the similarities and differences of Ru catalysis in these reactions. Finally, an overview of this area and opportunities for further investigation are also provided.

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Confined Ru Nanocatalysts on Surface to Enhance Ammonia Synthesis: An In situ ETEM Study

Cited by 11 publications

References 69 publications

Essential Role of Ru–Anion Interaction in Ru-Based Ammonia Synthesis Catalysts

Essential Role of Ru–Anion Interaction in Ru-Based Ammonia Synthesis Catalysts

Integrating Dissociative and Associative Routes for Efficient Ammonia Synthesis over a TiCN-Promoted Ru-Based Catalyst

Challenges and Opportunities of Ru-Based Catalysts toward the Synthesis and Utilization of Ammonia

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