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211 results on '"Chang, Chun-Ran"'

1. Finding Natural, Dense, and Stable Frustrated Lewis Pairs on Wurtzite Crystal Surfaces

Author

Yu, Xi-Yang, Huang, Zheng-Qing, Ban, Tao, Xu, Yun-Hua, Liu, Zhong-Wen, and Chang, Chun-Ran

Subjects
Condensed Matter - Materials Science
Abstract

The surface frustrated Lewis pairs (SFLPs) open up new opportunities for substituting noble metals in the activation and conversion of stable molecules. However, the applications of SFLPs on a larger scale are impeded by the complex construction process, low surface density, and sensitivity to the reaction environment. Herein, wurtzite-structured crystals such as GaN, ZnO, and AlP are found for developing natural, dense, and stable SFLPs. It is revealed that the SFLPs can naturally exist on the (100) and (110) surfaces of wurtzite-structured crystals. All the surface cations and anions serve as the Lewis acid and Lewis base in SFLPs, respectively, contributing to the surface density of SFLPs as high as 7.26 x 1014 cm-2. Ab initio molecular dynamics simulations indicate that the SFLPs can keep stable under high temperatures and the reaction atmospheres of CO and H2O. Moreover, outstanding performance for activating the given small molecules is achieved on these natural SFLPs, which originates from the optimal orbital overlap between SFLPs and small molecules. Overall, these findings not only provide a simple method to obtain dense and stable SFLPs but also unfold the nature of SFLPs toward the facile activation of small molecules.

Published
2023

20. Nondissociative Activated Dihydrogen Binding on CeO2Revealed by High-Pressure Operando Solid-State NMR Spectroscopy

Author

Yao, Xinlong, Ji, Yi, Huang, Zheng-Qing, Zhao, Zhenchao, Gao, Pan, Guo, Meiling, Liu, Xuebin, Meng, Caixia, Fu, Qiang, Chang, Chun-Ran, Bao, Xinhe, and Hou, Guangjin

Abstract

Dihydrogen complexes, which retain the H–H bond, have been extensively studied in molecular science and found to be prevalent in homogeneous and enzymatic catalysis. However, their counterparts in heterogeneous catalysis, specifically nondissociative chemisorbed dihydrogen binding on the catalyst surface, are rarely reported experimentally. This scarcity is due to the complexity of typical material surfaces and the lack of effective characterization techniques to prove and distinguish various dihydrogen binding modes. Herein, using high-pressure operando solid-state NMR technology, we report the first unambiguous experimental observation of activated dihydrogen binding on a reduced ceria catalyst through interactions with surface oxygen vacancies. By employing versatile NMR structural and dynamical analysis methods, we establish a proportional relationship between the degree of ceria surface reduction and dihydrogen binding, as evidenced by NMR observations of H-D through-bond coupling (JHD), T1relaxation, and proton isotropic chemical shifts. In situNMR analysis further reveals the participation of bound dihydrogen species in a room-temperature ethylene hydrogenation reaction. The remarkable similarities between surface-activated dihydrogen in heterogeneous catalysis and dihydrogen model molecular complexes can provide valuable insights into the hydrogenation mechanism for many other solid catalysts, potentially enhancing hydrogen utilization.

Published
2024
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23. Finding Natural, Dense, and Stable Frustrated Lewis Pairs on Wurtzite Crystal Surfaces for Small‐Molecule Activation.

Author

Yu, Xi‐Yang, Huang, Zheng‐Qing, Ban, Tao, Xu, Yun‐Hua, Liu, Zhong‐Wen, and Chang, Chun‐Ran

Subjects
LEWIS pairs (Chemistry), CRYSTAL surfaces, WURTZITE, LEWIS bases, LEWIS acids, DIAMOND crystals, GALLIUM nitride films
Abstract

The surface frustrated Lewis pairs (SFLPs) open up new opportunities for substituting noble metals in the activation and conversion of stable molecules. However, the applications of SFLPs on a larger scale are impeded by the complex construction process, low surface density, and sensitivity to the reaction environment. Herein, wurtzite‐structured crystals such as GaN, ZnO, and AlP are found for developing natural, dense, and stable SFLPs. It is revealed that the SFLPs can naturally exist on the (100) and (110) surfaces of wurtzite‐structured crystals. All the surface cations and anions serve as the Lewis acid and Lewis base in SFLPs, respectively, contributing to the surface density of SFLPs as high as 7.26×1014 cm−2. Ab initio molecular dynamics simulations indicate that the SFLPs can keep stable under high temperatures and the reaction atmospheres of CO and H2O. Moreover, outstanding performance for activating the given small molecules is achieved on these natural SFLPs, which originates from the optimal orbital overlap between SFLPs and small molecules. Overall, these findings not only provide a simple method to obtain dense and stable SFLPs but also unfold the nature of SFLPs toward the facile activation of small molecules. [ABSTRACT FROM AUTHOR]

Published
2024
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32. Engineering the electronic structure of single atom Ru sites via compressive strain boosts acidic water oxidation electrocatalysis

Author

Yao, Yancai, Hu, Sulei, Chen, Wenxing, Huang, Zheng-Qing, Wei, Weichen, Yao, Tao, Liu, Ruirui, Zang, Ketao, Wang, Xiaoqian, Wu, Geng, Yuan, Wenjuan, Yuan, Tongwei, Zhu, Baiquan, Liu, Wei, Li, Zhijun, He, Dongsheng, Xue, Zhenggang, Wang, Yu, Zheng, Xusheng, Dong, Juncai, Chang, Chun-Ran, Chen, Yanxia, Hong, Xun, Luo, Jun, Wei, Shiqiang, Li, Wei-Xue, Strasser, Peter, Wu, Yuen, and Li, Yadong

Published
2019
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36. DFT studies of CO reaction behavior on α-Fe2O3(001) oxygen-vacancy surface in chemical looping reforming.

Author

Zhang, Hui-Xin, Huang, Zheng-Qing, Ban, Tao, Su, Xue, Yang, Bolun, and Chang, Chun-Ran

Subjects
OXYGEN carriers, DENSITY functional theory, ACTIVATION energy
Abstract

Chemical looping reforming of methane to syngas (CO and H2) is one of the most promising routes for methane utilization, where the further reaction of CO on oxygen carrier surfaces is a primary determinant of CO selectivity. In this work, the effects of oxygen vacancy (Vo) on CO desorption, CO oxidation, and CO dissociation are systematically studied by using density functional theory calculattions. Our calculated results reveal that increasing Vo concentration can weaken CO desorption at Fe sites due to the enhanced localization of electrons in the Fe atoms. Also, the increase in Vo concentration from 1/12 ML to 1/6 ML leads to a dramatic increase of activation energy in the CO oxidation from 0.64 eV to 1.10 eV. Moreover, the increase in Vo concentration is conducive to CO dissociation, but the dissociation is still almost impossible due to the high reaction energies (large than 3.00 eV). Considering these three reaction paths, CO desorption can proceed spontaneously at reaction temperatures above 900 K. Increasing Vo concentration can improve the selectivity of syngas production due to the less favorable CO oxidation compared with CO desorption at high Vo concentrations (1/6 ML). This work reveals the microscopic mechanism that CO selectivity rises in the CLRM as the degree of Fe2O3 reduction increases. [ABSTRACT FROM AUTHOR]

Published
2024
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42. Natural, Dense, and Stable Frustrated Lewis Pairs on Wurtzite Crystal Surfaces

Author

Yu, Xi-Yang, Ban, Tao, Xu, Yun-Hua, Liu, Zhong-Wen, Huang, Zheng-Qing, and Chang, Chun-Ran

Subjects
Condensed Matter - Materials Science, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences
Abstract

The surface frustrated Lewis pairs (SFLPs), in which the Lewis acid and Lewis base are sterically hindered, open up new opportunities for small molecule activation. However, the construction of SFLPs currently needs various elaborate synthesis processes, leading to the low density and low stability of the SFLPs. Herein, the wurtzite crystal structures are discovered for developing natural SFLPs possessing dense and stable active sites. The SFLPs can naturally exist on the (100) and (110) surfaces of wurtzite-structured GaN, ZnO, and AlP. All the surface cations and anions serve as the Lewis acid and Lewis base in SFLPs, respectively, contributing to a high SFLPs density of 7.26 * 10^14 cm^(-2) on GaN(110). Ab initio molecular dynamics simulations reveal that the SFLPs can maintain stable structures under high temperatures and the atmospheres of CO and H2O. Moreover, outstanding performance for activating small molecules (H2, CH4, and NH3) is demonstrated on these natural SFLPs, which originated from the unique orbital orientation of SFLPs. Overall, these findings provide a simple method to obtain dense and stable SFLPs and unfold the nature of SFLPs toward the facile activation of small molecules.

Published
2023
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43. Screening silica-confined single-atom catalysts for nonoxidative conversion of methane.

Author

He, Shu-Yue, Li, Teng-Hao, Huang, Zheng-Qing, Liu, Yuan, Li, Jun, and Chang, Chun-Ran

Subjects
PRECIOUS metals, METHANE, IRON catalysts, TRANSITION metals, CATALYSTS, FERMI level, ALKENES
Abstract

The development of a single-atom iron catalyst (Fe©SiO2) for the direct conversion of methane to olefins, aromatics, and hydrogen is a breakthrough in the field of nonoxidative conversion of methane (NCM). However, the optimization of the catalyst remains desirable for industrial applications. Herein, 25 transition metals, including Sc, Ti, V, Cr, Mn, Co, Ni, Cu, Y, Zr, Nb, Mo, Tc, Ru, Rh, Pd, Ag, Hf, Ta, W, Re, Os, Ir, Pt, and Au, are selected to replace the central Fe atom for screening out better single-atom catalysts for the NCM. Using the performance on the activation of methane, such as the adsorption energy of methane, the dissociation energy, and the barrier of methane as the screening descriptors, Mn©SiO2, Fe©SiO2, W©SiO2, and Re©SiO2 are first screened out. The remarkable performance of the four catalysts on methane activation is attributed to the unique geometric structure and the d z 2 orbitals of the central metal crossing over the Fermi level, which can benefit the interaction between methane and the catalysts. By considering the catalytic performance on the whole pathway of methane to ethylene, W©SiO2 is finally selected as the most active catalyst for the NCM, which has the lowest rate-determining barrier of 1.62 eV and the smallest free energy span (1.06 eV) of the overall catalytic cycle. [ABSTRACT FROM AUTHOR]

Published
2021
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