Silver and Copper Dual Single Atoms Boosting Direct Oxidation of Methane to Methanol via Synergistic Catalysis

Yu, Baiyang; Cheng, Lu; Dai, Sheng; Jiang, Yongjun; Yang, Bing; Li, Hong; Zhao, Yongchun; Xu, Jing; Zhang, Ying; Pan, Chengsi; Cao, Xiaoming; Zhu, Yongfa; Lou, Yang

doi:10.1002/advs.202302143

Cited by 31 publications

(2 citation statements)

References 74 publications

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“…To date, various catalysts have been engineered to enhance methanol synthesis. − For example, innovative combinations of copper-based catalysts with different metal oxides have been explored. Researchers have also finely tuned the precipitation conditions by adjusting factors like additives, aging, pH, precipitating agents, solvents, and temperature. − While some commercial catalysts have been optimized to favor methanol formation, the mechanisms that inhibit ethanol production remain elusive. , Consequently, a deeper understanding of these inhibition mechanisms to design superior catalysts is highly sought after.…”

Section: Introductionmentioning

confidence: 99%

Strong Cu/ZnO Interfacial Interaction Induced by ZrO₂ Promoter Suppressing the Ethanol Formation in Industrial Methanol Synthesis

Yu,

Lin,

Song

et al. 2024

Ind. Eng. Chem. Res.

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The presence of ethanol as an impurity in industrial methanol significantly degrades the quality of the downstream products. Addressing the challenge of suppressing ethanol formation remains crucial in the synthesis of industrial methanol. In this context, we systematically characterized a series of commercial catalysts and evaluated their catalytic performance for methanol synthesis to elucidate the relationship between the catalyst structure and ethanol selectivity. Our performance tests indicate that the Cu−Zn−Al commercial catalyst (NG), enhanced with a ZrO 2 promoter, can effectively inhibit ethanol formation, reducing it to approximately 580 ppm after 1000 h. The ZrO 2 promoter stabilizes Cu 0 , ensuring it is highly dispersed and maintains a homogeneous structure, which is pivotal for the catalyst's exceptional performance. Analysis through temperature-programmed desorption and density functional theory (DFT) demonstrates that the high dispersity of Cu 0 enhances the adsorption of CO and H 2 . Additionally, a uniform Cu 0 active site structure contributes to the increased methanol selectivity while simultaneously suppressing ethanol formation. This study underscores the significant potential of incorporating a ZrO 2 promoter in catalysts to effectively suppress ethanol production under industrial operating conditions.

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Section: Introductionmentioning

confidence: 99%

Strong Cu/ZnO Interfacial Interaction Induced by ZrO₂ Promoter Suppressing the Ethanol Formation in Industrial Methanol Synthesis

Yu,

Lin,

Song

et al. 2024

Ind. Eng. Chem. Res.

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“…Dual Single-Atom Compounds (DSACs) have emerged as a focal point in the field of catalysis, drawing widespread attention due to their properties and potential application value. , Characterized by the uniform dispersion of two distinct metal atoms on a singular support, this advanced catalytic system not only inherits the high activity and selectivity of Single-Atom Catalysts (SACs) − but also amplifies catalytic performance through the synergistic interaction between the two metal atoms. − However, despite the immense potential of DSACs, there are key challenges to overcome in their synthesis. First, current synthesis methods are often complex and costly, limiting their broad adoption in industrial applications. − Second, the stability of DSACs, − especially the phenomena of deactivation during catalytic reactions, has become a major barrier to their long-term stable application. Additionally, the purity of the catalyst is an issue that cannot be overlooked, as any impurities or cluster structures can adversely affect its performance and activity.…”

Section: Introductionmentioning

confidence: 99%

Entropy-Engineered Middle-In Synthesis of Dual Single-Atom Compounds for Nitrate Reduction Reaction

Hu,

Lan,

et al. 2024

ACS Nano

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Despite the immense potential of Dual Single-Atom Compounds (DSACs), the challenges in their synthesis process, including complexity, stability, purity, and scalability, remain primary concerns in current research. Here, we present a general strategy, termed "Entropy-Engineered Middle-In Synthesis of Dual Single-Atom Compounds" (EEMIS-DSAC), which is meticulously crafted to produce a diverse range of DSACs, effectively addressing the aforementioned issues. Our strategy integrates the advantages of both bottom-up and top-down paradigms, proposing an insight into optimizing the catalyst structure. The as-fabricated DSACs exhibited excellent activity and stability in the nitrate reduction reaction (NO 3 RR). In a significant advancement, our prototypical CuNi DSACs demonstrated outstanding performance under conditions reminiscent of industrial wastewater. Specifically, under a NO 3 − concentration of 2000 ppm, it yielded a Faradaic efficiency (FE) for NH 3 of 96.97%, coupled with a mass productivity of 131.47 mg h −1 mg −1 and an area productivity of 10.06 mg h −1 cm −2 . Impressively, even under a heightened NO 3 − concentration of 0.5 M, the FE for NH 3 peaked at 90.61%, with a mass productivity reaching 1024.50 mg h −1 mg −1 and an area productivity of 78.41 mg h −1 cm −2 . This work underpins the potential of the EEMIS-DSAC approach, signaling a frontier for high-performing DSACs.

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Photocatalytic Coupling of CH₄ and CO₂ to Ethanol on Asymmetric Ce−O−Zn Sites

Hao,

Chen,

Peng

et al. 2023

Adv Funct Materials

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Partial oxidation of methane (CH4) to value‐added products is significantly challenging due to the highly inert chemical property of CH4 at ambient conditions and easy over‐oxidation into carbon dioxide (CO2) or carbon monoxide (CO) at elevated temperatures and pressures. Targeting this challenge, the efficient photocatalytic coupling of CO2 and CH4 into ethanol is demonstrated, using a cerium (Ce)‐doped zinc oxide (ZnO) photocatalyst with abundant Ce─O─Zn units. Under light illumination, CO2 is adsorbed on the Ce atoms and photo‐reduced to CO, and CH4 is captured by the Zn atoms and photo‐oxidized to hydroperoxymethane (CH3OOH). The close proximity of Ce and Zn atoms on the Ce─O─Zn units allowed to further efficiently couple the as‐formed CO and CH3OOH into ethanol. Without additional Oxygen (O2) oxidant or sacrificial regent, the ethanol production rate reached 580 µmol g−1 h−1, substantially exceeding previously reports on photocatalytic CH4 oxidation. This work features to convert two greenhouse gases into value‐added chemicals with adjacent and asymmetric reaction sites, suggesting attractive potentials for CH4 and CO2 utilization.

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Silver and Copper Dual Single Atoms Boosting Direct Oxidation of Methane to Methanol via Synergistic Catalysis

Cited by 31 publications

References 74 publications

Strong Cu/ZnO Interfacial Interaction Induced by ZrO₂ Promoter Suppressing the Ethanol Formation in Industrial Methanol Synthesis

Strong Cu/ZnO Interfacial Interaction Induced by ZrO₂ Promoter Suppressing the Ethanol Formation in Industrial Methanol Synthesis

Entropy-Engineered Middle-In Synthesis of Dual Single-Atom Compounds for Nitrate Reduction Reaction

Photocatalytic Coupling of CH₄ and CO₂ to Ethanol on Asymmetric Ce−O−Zn Sites

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Silver and Copper Dual Single Atoms Boosting Direct Oxidation of Methane to Methanol via Synergistic Catalysis

Cited by 31 publications

References 74 publications

Strong Cu/ZnO Interfacial Interaction Induced by ZrO2 Promoter Suppressing the Ethanol Formation in Industrial Methanol Synthesis

Strong Cu/ZnO Interfacial Interaction Induced by ZrO2 Promoter Suppressing the Ethanol Formation in Industrial Methanol Synthesis

Entropy-Engineered Middle-In Synthesis of Dual Single-Atom Compounds for Nitrate Reduction Reaction

Photocatalytic Coupling of CH4 and CO2 to Ethanol on Asymmetric Ce−O−Zn Sites

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Strong Cu/ZnO Interfacial Interaction Induced by ZrO₂ Promoter Suppressing the Ethanol Formation in Industrial Methanol Synthesis

Strong Cu/ZnO Interfacial Interaction Induced by ZrO₂ Promoter Suppressing the Ethanol Formation in Industrial Methanol Synthesis

Photocatalytic Coupling of CH₄ and CO₂ to Ethanol on Asymmetric Ce−O−Zn Sites