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Your search keyword '"Wang, Wei‐wei"' showing total 18 results
Start Over Author "Wang, Wei‐wei" Journal nature communications
18 results on '"Wang, Wei‐wei"'

10. Direct cleavage of C=O double bond in CO2 by the subnano MoOx surface on Mo2N.

Author

Liu, Hao-Xin, Wang, Wei-Wei, Fu, Xin-Pu, Liu, Jin-Cheng, and Jia, Chun-Jiang

Subjects
DOUBLE bonds, SCISSORS & shears, CATALYST synthesis, HYDROGENATION, HETEROSTRUCTURES
Abstract

Compared to H2-assisted activation mode, the direct dissociation of CO2 into carbonyl (*CO) with a simplified reaction route is advantageous for CO2-related synthetic processes and catalyst upgrading, while the stable C = O double bond makes it very challenging. Herein, we construct a subnano MoO3 layer on the surface of Mo2N, which provides a dynamically changing surface of MoO3↔MoOx (x < 3) for catalyzing CO2 hydrogenation. Rich oxygen vacancies on the subnano MoOx surface with a high electron donating capacity served as a scissor to directly shear the C = O double bond of CO2 to form CO at a high rate. The O atoms leached in CO2 dissociation are removed timely by H2 to regenerate active oxygen vacancies. Owing to the greatly enhanced dissociative activation of CO2, this MoOx/Mo2N catalyst without any supported active metals shows excellent performance for catalyzing CO2 hydrogenation to CO. The construction of highly disordered defective surface on heterostructures paves a new pathway for molecule activation. The direct dissociation of CO2 into carbonyl (*CO) via a simplified reaction pathway benefits CO2-related synthesis and catalyst improvement, though the stability of the C = O double bond poses a significant challenge. Here, the authors design a subnano MoO3 layer on the surface of Mo2N, offering a dynamically adaptive surface for catalyzing CO2 hydrogenation. [ABSTRACT FROM AUTHOR]

Published
2024
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14. Resolving nanostructure and chemistry of solid-electrolyte interphase on lithium anodes by depth-sensitive plasmon-enhanced Raman spectroscopy.

Author

Gu, Yu, You, En-Ming, Lin, Jian-De, Wang, Jun-Hao, Luo, Si-Heng, Zhou, Ru-Yu, Zhang, Chen-Jie, Yao, Jian-Lin, Li, Hui-Yang, Li, Gen, Wang, Wei-Wei, Qiao, Yu, Yan, Jia-Wei, Wu, De-Yin, Liu, Guo-Kun, Zhang, Li, Li, Jian-Feng, Xu, Rong, Tian, Zhong-Qun, and Cui, Yi

Subjects
RAMAN spectroscopy, SERS spectroscopy, COPPER, SURFACE plasmons, GOLD nanoparticles, ANODES, FLUOROETHYLENE
Abstract

The solid-electrolyte interphase (SEI) plays crucial roles for the reversible operation of lithium metal batteries. However, fundamental understanding of the mechanisms of SEI formation and evolution is still limited. Herein, we develop a depth-sensitive plasmon-enhanced Raman spectroscopy (DS-PERS) method to enable in-situ and nondestructive characterization of the nanostructure and chemistry of SEI, based on synergistic enhancements of localized surface plasmons from nanostructured Cu, shell-isolated Au nanoparticles and Li deposits at different depths. We monitor the sequential formation of SEI in both ether-based and carbonate-based dual-salt electrolytes on a Cu current collector and then on freshly deposited Li, with dramatic chemical reconstruction. The molecular-level insights from the DS-PERS study unravel the profound influences of Li in modifying SEI formation and in turn the roles of SEI in regulating the Li-ion desolvation and the subsequent Li deposition at SEI-coupled interfaces. Last, we develop a cycling protocol that promotes a favorable direct SEI formation route, which significantly enhances the performance of anode-free Li metal batteries. The solid-electrolyte interphase is crucial for most batteries, but its characterization is challenging. Here, authors develop a depth-sensitive plasmon-enhanced Raman spectroscopy method to enable in-situ and nondestructive resolving of its structure and chemistry as well as formation mechanisms. [ABSTRACT FROM AUTHOR]

Published
2023
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16. Ptn–Ov synergistic sites on MoOx/γ-Mo2N heterostructure for low-temperature reverse water–gas shift reaction.

Author

Liu, Hao-Xin, Li, Jin-Ying, Qin, Xuetao, Ma, Chao, Wang, Wei-Wei, Xu, Kai, Yan, Han, Xiao, Dequan, Jia, Chun-Jiang, Fu, Qiang, and Ma, Ding

Subjects
WATER-gas, WATER gas shift reactions, HETEROGENEOUS catalysis, CATALYTIC activity, ATOMS, LOW temperatures
Abstract

In heterogeneous catalysis, the interface between active metal and support plays a key role in catalyzing various reactions. Specially, the synergistic effect between active metals and oxygen vacancies on support can greatly promote catalytic efficiency. However, the construction of high-density metal-vacancy synergistic sites on catalyst surface is very challenging. In this work, isolated Pt atoms are first deposited onto a very thin-layer of MoO3 surface stabilized on γ-Mo2N. Subsequently, the Pt–MoOx/γ-Mo2N catalyst, containing abundant Pt cluster-oxygen vacancy (Ptn–Ov) sites, is in situ constructed. This catalyst exhibits an unmatched activity and excellent stability in the reverse water-gas shift (RWGS) reaction at low temperature (300 °C). Systematic in situ characterizations illustrate that the MoO3 structure on the γ-Mo2N surface can be easily reduced into MoOx (2 < x < 3), followed by the creation of sufficient oxygen vacancies. The Pt atoms are bonded with oxygen atoms of MoOx, and stable Pt clusters are formed. These high-density Ptn–Ov active sites greatly promote the catalytic activity. This strategy of constructing metal-vacancy synergistic sites provides valuable insights for developing efficient supported catalysts. Constructing effective synergistic sites between multiple components in supported catalysts is the key to improve catalytic performance. Here the authors utilized the stress of MoO3/γ-Mo2N structure and the interaction between Pt and support to construct an effective catalytic interface for the low-temperature reverse water–gas shift reaction. [ABSTRACT FROM AUTHOR]

Published
2022
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17. Catalytically efficient Ni-NiOx-Y2O3 interface for medium temperature water-gas shift reaction.

Author

Xu, Kai, Ma, Chao, Yan, Han, Gu, Hao, Wang, Wei-Wei, Li, Shan-Qing, Meng, Qing-Lu, Shao, Wei-Peng, Ding, Guo-Heng, Wang, Feng Ryan, and Jia, Chun-Jiang

Subjects
WATER gas shift reactions, WATER-gas, CATALYSTS, CATALYTIC activity, METALLIC oxides, TEMPERATURE
Abstract

The metal-support interfaces between metals and oxide supports have long been studied in catalytic applications, thanks to their significance in structural stability and efficient catalytic activity. The metal-rare earth oxide interface is particularly interesting because these early transition cations have high electrophilicity, and therefore good binding strength with Lewis basic molecules, such as H2O. Based on this feature, here we design a highly efficient composite Ni-Y2O3 catalyst, which forms abundant active Ni-NiOx-Y2O3 interfaces under the water-gas shift (WGS) reaction condition, achieving 140.6 μmolCO gcat−1 s−1 rate at 300 °C, which is the highest activity for Ni-based catalysts. A combination of theory and ex/in situ experimental study suggests that Y2O3 helps H2O dissociation at the Ni-NiOx-Y2O3 interfaces, promoting this rate limiting step in the WGS reaction. Construction of such new interfacial structure for molecules activation holds great promise in many catalytic systems. Developing effective and stable catalytic interfaces in the medium temperature region is a practical route to replace the existing water gas shift (WGS) process. Here the authors designed a composite Ni-Y2O3 catalyst achieving the highest WGS activity for Ni based catalysts. [ABSTRACT FROM AUTHOR]

Published
2022
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18. Construction of stabilized bulk-nano interfaces for highly promoted inverse CeO2/Cu catalyst.

Author

Yan, Han, Yang, Chun, Shao, Wei-Peng, Cai, Li-Hua, Wang, Wei-Wei, Jin, Zhao, and Jia, Chun-Jiang

Subjects
WATER gas shift reactions, CERIUM oxides, NANOPARTICLES, COPPER catalysts, CHEMICAL stability
Abstract

As the water-gas shift (WGS) reaction serves as a crucial industrial process, strategies for developing robust WGS catalysts are highly desiderated. Here we report the construction of stabilized bulk-nano interfaces to fabricate highly efficient copper-ceria catalyst for the WGS reaction. With an in-situ structural transformation, small CeO2 nanoparticles (2–3 nm) are stabilized on bulk Cu to form abundant CeO2-Cu interfaces, which maintain well-dispersed under reaction conditions. This inverse CeO2/Cu catalyst shows excellent WGS performances, of which the activity is 5 times higher than other reported Cu catalysts. Long-term stability is also very solid under harsh conditions. Mechanistic study illustrates that for the inverse CeO2/Cu catalyst, superb capability of H2O dissociation and CO oxidation facilitates WGS process via the combination of associative and redox mechanisms. This work paves a way to fabricate robust catalysts by combining the advantages of bulk and nano-sized catalysts. Catalysts with such inverse configurations show great potential in practical WGS applications. Cu-CeO2 has been considered as promising alternative to Cu-Zn-Al catalyst for water-gas shift (WGS) reaction, but it still suffers from low activity caused by Cu sintering. Here, the authors develop inverse CeO2/Cu catalyst with remarkable activity and stability in WGS via construction of stabilized bulk-nano interfaces. [ABSTRACT FROM AUTHOR]

Published
2019
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