Molybdenum Oxycarbide Supported Rh‐Clusters with Modulated Interstitial C–O Microenvironments for Promoting Hydrogen Evolution

Wang, Weiwen; Geng, Wei; Zhang, Lu; Zhao, Zhenyang; Zhang, Zhen; Ma, Tian; Cheng, Chong; Liu, Xikui; Zhang, Yanning; Li, Shuang

doi:10.1002/smll.202206808

Cited by 15 publications

(12 citation statements)

References 50 publications

(60 reference statements)

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“…For instance, molybdenum oxycarbide-supported Rh clusters (Rh/ MoOC) were fabricated and displayed the characteristic XRD diffraction peaks of cubic-phase MoOC and cubic-phase Rh (Figure 8e). 53 The suitable lattice match between the Rh nanocluster and MoOC maintained the phase separation and produced a stable heterostructure. The Rh K-edge XANES spectrum of Rh/MoOC demonstrated obvious electron transfer from Rh to MoOC (Figure 8f).…”

Section: Rh/compoundmentioning

confidence: 98%

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Design and Performance of Rh Nanocatalysts for Boosted H₂ Generation in Alkaline Media

Guo,

Tong,

Yang

2023

Acc. Mater. Res.

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Metrics & MoreArticle Recommendations CONSPECTUS: Hydrogen generation from electrocatalytic water splitting is widely regarded as an important energy conversion process based on its high compatibility with clean and renewable energy sources. It thus has the potential to help society achieve cleanness and sustainability. For the long-term production of highly purified hydrogen for industrial applications, it is preferred for the hydrogen evolution reaction (HER) to occur under mild working conditions or in alkaline media. However, such practical reaction efficiencies are hindered by additional water dissociation and multistep electron transfer. This stems from the sluggish kinetics of the HER in alkaline media, where the reaction rate is 2 to 3 orders of magnitude lower than in acidic media. Up to now, Pt has been extensively accepted as the symbolic catalyst for HER thanks to its appropriate hydrogen adsorption capability. Unfortunately, its activity is not acceptable due to its poor efficiency for water dissociation in alkaline solutions. In this regard, advanced catalysts that have both high catalytic activity for water dissociation and an appropriate hydrogen adsorption capacity are highly desired. Among the reported Pt-free catalysts for alkaline HER, Rh-based electrocatalysts exhibit obviously enhanced performances. It has been experimentally and theoretically confirmed that the Rh catalyst is located near the top of the Trasatti volcano plot for the HER, indicating its suitable adsorption energy of H* to facilitate the HER. In addition, the Rh catalyst possesses stronger competence for water dissociation than the Pt catalyst, which is a prerequisite for highly effective alkaline HER. In this context, a series of experiments with Rh-based electrocatalysts toward the alkaline HER have been actualized over the past decades. These proposed Rhbased catalysts have displayed impressive performances and promising prospects for hydrogen production. To realize the industrial application of hydrogen generation, Rh-based catalysts still require development, such as with the conceptual design of the catalysts and corresponding advanced synthesis methods. In short, further improvement of the catalytic performances of Rh-based catalysts depends on the development of various regulation strategies.In this Account, we highlight the recent progress and achievements of the regulation strategies for Rh-based catalysts and the corresponding enhancement principle for alkaline HER. We start with an introduction and comparison of the different mechanisms in acidic versus alkaline HER processes, emphasizing the principles of designing highly efficient catalysts toward alkaline HER. On the basis of previously reported studies, we conduct an in-depth discussion about the regulation strategies for Rh-based electrocatalysts and the performance optimization toward alkaline HER. This part is divided into three sections: structural engineering (e.g., size, alloy, and morphology regulation), surface engineering (e.g., element doping, facet ...

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Section: Rh/compoundmentioning

confidence: 98%

Section: Design Of Rh-based Electrocatalysts For Hermentioning

confidence: 99%

Design and Performance of Rh Nanocatalysts for Boosted H₂ Generation in Alkaline Media

Guo,

Tong,

Yang

2023

Acc. Mater. Res.

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“…Besides the above-mentioned metal oxides, plenty of emerged metal oxides, including W 18 O 49 , MoO 3 , and mixed metal oxides, have also been proven as excellent catalysts in recent years. [11,127,128] Fortunately, evidence has illustrated that MoO 3 NPs with the metal catalytic center of sulfite oxidase (SuO x ) can facilitate the transformation of sulfite to sulfate, especially in SuO x deficiency cells, to show SuO x -like activity. Besides, introducing oxygen vacancies into MoO 3 NPs is expected to modulate the defective structures and improve their SuO x activity.…”

Section: Other Metal Oxidesmentioning

confidence: 99%

Tunable Structured Metal Oxides for Biocatalytic Therapeutics

Yuan

Gao

et al. 2023

Adv Funct Materials

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The past few decades have witnessed the flourish of creating metal oxides for biocatalytic therapeutics due to their structural diversities, feasible modifications, tunable catalytic sites, and low cost when compared to their natural enzyme counterparts. Here, in this timely review, the most recent progress and future trends in engineering tunable structured metal oxides and decoding their structure‐reactivity relationships for biocatalytic therapeutics is comprehensively summarized. At first, the fundamental activities, evaluations, and mechanisms of metal oxide‐based biocatalysts are carefully disclosed. Subsequently, the merits, design methods, and state‐of‐art achievements of different types of nanostructured and biofunctionalized metal oxides are thoroughly discussed. Thereafter, it provides detailed comments on the catalytic center modulation strategies to engineer metal oxides for efficient reactive oxygen species (ROS)‐catalysis, including atomic catalytic site engineering, heterostructures, and support effects. Furthermore, the representative applications of these ROS‐catalytic metal oxides have been systematically summarized, such as catalytic disinfections, cancer therapies, ROS scavenging and anti‐inflammations, biocatalytic sensors, as well as corresponding toxicities. Finally, current challenges and future perspectives are also highlighted. It is believed that this review can provide cutting‐edge and multidisciplinary instruction for the future design of ROS‐catalytic metal oxides and stimulate their widespread utilization in broad therapeutic applications.

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“…[ 14–17 ] Compared with their natural counterpart, the transition metal compounds‐based biocatalysts display several merits, such as low cost, tunable electronic and physicochemical properties, [ 18–20 ] and high stability and recyclability. [ 4–21,22 ]…”

Section: Introductionmentioning

confidence: 99%

Ultralow Ru Single Atoms Confined in Cerium Oxide Nanoglues for Highly‐Sensitive and Robust H₂O₂‐Related Biocatalytic Diagnosis

Yuan,

Li,

et al. 2023

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Exploring highly efficient, portable, and robust biocatalysts is a great challenge in colorimetric biosensors. To overcome the challenging states in creating single‐atom biocatalysts, such as insufficient activity and stability, here, this work has engineered a unique CeO2 support as nanoglue to tightly anchor the Ru single‐atom sites (CeO2‐Ru) with strong electronic coupling for achieving highly sensitive and robust H2O2‐related biocatalytic diagnosis. The morphology and chemical/electronic structure analysis demonstrates that the Ru atoms are well‐dispersed on CeO2 surface to form high‐density active sites. Benefiting from the unique structure, the prepared CeO2‐Ru exhibits outstanding peroxidase (POD) like catalytic activity and selectivity to H2O2. Steady‐state kinetic study results show that the CeO2‐Ru presents the highest Vmax and turnover number than the state‐of‐the‐art POD‐like biocatalysts. Consequently, the CeO2‐Ru discloses a high efficiency, good selectivity, and robust stability in the colorimetric detection of L‐cysteine, glucose, and uric acid. Notably, the limit of detection (LOD) can reach 0.176 × 10−3 m for the L‐cysteine, 0.095 × 10−3 m for the glucose, and 0.088 × 10−3 m for the uric acid via cascade reaction. This work suggests that the proposed unique CeO2 nanoglue will offer a new path to create single‐atom noble metal biocatalysts and take a step closer to future biotherapeutic and biocatalytic applications.

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Molybdenum Oxycarbide Supported Rh‐Clusters with Modulated Interstitial C–O Microenvironments for Promoting Hydrogen Evolution

Cited by 15 publications

References 50 publications

Design and Performance of Rh Nanocatalysts for Boosted H₂ Generation in Alkaline Media

Design and Performance of Rh Nanocatalysts for Boosted H₂ Generation in Alkaline Media

Tunable Structured Metal Oxides for Biocatalytic Therapeutics

Ultralow Ru Single Atoms Confined in Cerium Oxide Nanoglues for Highly‐Sensitive and Robust H₂O₂‐Related Biocatalytic Diagnosis

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Molybdenum Oxycarbide Supported Rh‐Clusters with Modulated Interstitial C–O Microenvironments for Promoting Hydrogen Evolution

Cited by 15 publications

References 50 publications

Design and Performance of Rh Nanocatalysts for Boosted H2 Generation in Alkaline Media

Design and Performance of Rh Nanocatalysts for Boosted H2 Generation in Alkaline Media

Tunable Structured Metal Oxides for Biocatalytic Therapeutics

Ultralow Ru Single Atoms Confined in Cerium Oxide Nanoglues for Highly‐Sensitive and Robust H2O2‐Related Biocatalytic Diagnosis

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Product

Resources

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Design and Performance of Rh Nanocatalysts for Boosted H₂ Generation in Alkaline Media

Design and Performance of Rh Nanocatalysts for Boosted H₂ Generation in Alkaline Media

Ultralow Ru Single Atoms Confined in Cerium Oxide Nanoglues for Highly‐Sensitive and Robust H₂O₂‐Related Biocatalytic Diagnosis