I11-High Resolution Powder Diffraction
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Tianxiang
Chen
,
Yunong
Li
,
Ping-Luen
Ho
,
Kwan Chee
Leung
,
Jinjie
Liu
,
Ching Kit Tommy
Wun
,
Zehao
Li
,
Chiu Chung
Tang
,
Shogo
Kawaguchi
,
Tai-Sing
Wu
,
Yun-Liang
Soo
,
Jun
Yin
,
Shik Chi Edman
Tsang
,
Tsz Woon Benedict
Lo
Open Access
Abstract: A precise understanding of the structure–activity relationship of catalysts is crucial for catalysis research and is essential for rationalizing next-generation catalysts. As the size of catalysts decreases from nanometric to atomic dimensions, the focus on structure–activity relationship correlation has shifted from the “size effect” to the much more challenging “metal nuclearity effect”. However, precise synthesis and reliable characterization for structurally related solid atomic catalysts, such as single-, dual-, and triatom catalysts, still remain extremely challenging. Here, we present the controlled assembly of single-atomic Cu1, dual-atomic Cu2, and triatomic Cu3 supported on zeolites through an innovative atomically choreographed approach. For the first time, we have directly visualized the atomic features of Cu3 with respect to the zeolitic channels using double aberration-corrected scanning transmission electron microscopy (STEM). The structural and electronic properties of the catalysts have been characterized using synchrotron X-ray absorption spectroscopy, high-resolution synchrotron powder X-ray diffraction (PXRD), and density functional theory (DFT) calculations. We revealed the interplay among surface structures, adsorption configurations, catalytic reactivities (showing a significant 25-fold improvement), and product selectivity across structurally related species using a model methanol reforming reaction. We have successfully elucidated the relationship between the metal nuclearity effect and its activity and selectivity in a complex catalytic reaction. Our findings offer an unprecedented opportunity for the catalysis and materials community to finely manipulate the physicochemical properties of this category of solid atomic catalysts to achieve the desired reactivities and selectivities.
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May 2025
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Kwan Chee
Leung
,
Sungil
Hong
,
Guangchao
Li
,
Youdong
Xing
,
Bryan Kit Yue
Ng
,
Ping-Luen
Ho
,
Dongpei
Ye
,
Pu
Zhao
,
Ephraem
Tan
,
Olga
Safonova
,
Tai-Sing
Wu
,
Molly Meng-Jung
Li
,
Giannis
Mpourmpakis
,
Shik Chi Edman
Tsang
Open Access
Abstract: Catalytic NH3 synthesis and decomposition offer a new promising way to store and transport renewable energy in the form of NH3 from remote or offshore sites to industrial plants. To use NH3 as a hydrogen carrier, it is important to understand the catalytic functionality of NH3 decomposition reactions at an atomic level. Here, we report for the first time that Ru species confined in a 13X zeolite cavity display the highest specific catalytic activity of over 4000 h–1 for the NH3 decomposition with a lower activation barrier, compared to most reported catalytic materials in the literature. Mechanistic and modeling studies clearly indicate that the N–H bond of NH3 is ruptured heterolytically by the frustrated Lewis pair of Ruδ+–Oδ− in the zeolite identified by synchrotron X-rays and neutron powder diffraction with Rietveld refinement as well as other characterization techniques including solid-state nuclear magnetic resonance spectroscopy, in situ diffuse reflectance infrared transform spectroscopy, and temperature-programmed analysis. This contrasts with the homolytic cleavage of N–H displayed by metal nanoparticles. Our work reveals the unprecedented unique behavior of cooperative frustrated Lewis pairs created by the metal species on the internal zeolite surface, resulting in a dynamic hydrogen shuttling from NH3 to regenerate framework Brønsted acid sites that eventually are converted to molecular hydrogen.
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Jun 2023
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B07-C-Versatile Soft X-ray beamline: Ambient Pressure XPS and NEXAFS
B18-Core EXAFS
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Huihuang
Fang
,
Simson
Wu
,
Tugce
Ayvali
,
Jianwei
Zheng
,
Joshua
Fellowes
,
Ping-Luen
Ho
,
Kwan Chee
Leung
,
Alexander
Large
,
Georg
Held
,
Ryuichi
Kato
,
Kazu
Suenaga
,
Yves Ira A.
Reyes
,
Ho Viet
Thang
,
Hsin-Yi Tiffany
Chen
,
Shik Chi Edman
Tsang
Open Access
Abstract: Ammonia is regarded as an energy vector for hydrogen storage, transport and utilization, which links to usage of renewable energies. However, efficient catalysts for ammonia decomposition and their underlying mechanism yet remain obscure. Here we report that atomically-dispersed Ru atoms on MgO support on its polar (111) facets {denoted as MgO(111)} show the highest rate of ammonia decomposition, as far as we are aware, than all catalysts reported in literature due to the strong metal-support interaction and efficient surface coupling reaction. We have carefully investigated the loading effect of Ru from atomic form to cluster/nanoparticle on MgO(111). Progressive increase of surface Ru concentration, correlated with increase in specific activity per metal site, clearly indicates synergistic metal sites in close proximity, akin to those bimetallic N2 complexes in solution are required for the stepwise dehydrogenation of ammonia to N2/H2, as also supported by DFT modelling. Whereas, beyond surface doping, the specific activity drops substantially upon the formation of Ru cluster/nanoparticle, which challenges the classical view of allegorically higher activity of coordinated Ru atoms in cluster form (B5 sites) than isolated sites.
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Feb 2023
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Aug 2022
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B07-C-Versatile Soft X-ray beamline: Ambient Pressure XPS and NEXAFS
I11-High Resolution Powder Diffraction
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Abstract: Barium zirconate perovskites have been systematically investigated as protonic supports for ruthenium nanoparticles in the Haber–Bosch ammonia synthesis reaction. A series of supports based on barium zirconate were synthesized, for which the B-site of the ABO3 perovskite was doped with different aliovalent acceptor cations and in varying ratios, resulting in varying proton conductivities and trapping behaviors. Crucially, we provide direct evidence of the importance of a hydrogen-migration mechanism for ammonia synthesis over these proton-conducting materials from the studies of reaction kinetics, in situ X-ray photoelectron spectroscopy, and neutron powder diffraction (NPD), which requires the proper balance of oxygen vacancy concentration (B-site doping), trapping-site concentration, and proton-hopping activation energy. We report evidence of a large dynamic coverage of OH groups on the support and the first visualization of both weak and strong proton trap sites within the perovskite lattice through the use of NPD.
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Oct 2021
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I15-1-X-ray Pair Distribution Function (XPDF)
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Jianwei
Zheng
,
Lilin
Lu
,
Konstantin
Lebedev
,
Simson
Wu
,
Pu
Zhao
,
Ian J.
Mcpherson
,
Tai-Sing
Wu
,
Ryuichi
Kato
,
Yiyang
Li
,
Ping-Luen
Ho
,
Guangchao
Li
,
Linlu
Bai
,
Jianhui
Sun
,
Dharmalingam
Prabhakaran
,
Robert A.
Taylor
,
Yun-Liang
Soo
,
Kazu
Suenaga
,
Shik Chi Edman
Tsang
Abstract: Current industrial production of ammonia from the Haber-Bosch process and its transport concomitantly produces a large quantity of CO2. Herein, we successfully synthesize inorganic-structure-based catalysts with [Fe-S2-Mo] motifs with a connecting structure similar to that of FeMoco (a cofactor of nitrogenase) by placing iron atoms on a single molecular layer of MoS2 at various loadings. This type of new catalytic material functionally mimics the nitrogenase to convert N2 to ammonia and hydrogen in water without adding any sacrificial agent under visible-light illumination. Using the elevated temperature boosts the ammonia yield and the energy efficiency by one order of magnitude. The solar-to-NH3 energy-conversion efficiency can be up to 0.24% at 270°C, which is the highest efficiency among all reported photocatalytic systems. This method of ammonia production and the photocatalytic materials may open up an exciting possibility for the decentralization of ammonia production for fertilizer provision to local farmlands using solar illumination.
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Apr 2021
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B18-Core EXAFS
I11-High Resolution Powder Diffraction
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Pu
Zhao
,
Lin
Ye
,
Guangchao
Li
,
Chen
Huang
,
Simson
Wu
,
Ping-Luen
Ho
,
Haokun
Wang
,
Tatchamapan
Yoskamtorn
,
Denis
Sheptyakov
,
Giannantonio
Cibin
,
Angus I.
Kirkland
,
Chiu C.
Tang
,
Anmin
Zheng
,
Wenjuan
Xue
,
Donghai
Mei
,
Kongkiat
Suriye
,
Shik Chi Edman
Tsang
Abstract: Synthesizing atomically dispersed synergistic active pairs is crucial yet challenging in developing highly active heterogeneous catalysts for various industrially important reactions. Here, a single molecular Re species is immobilized on the inner surface of a Y zeolite with Brønsted acid sites (BASs) within atomic proximity to form Re OMS–BAS active pairs for the efficient catalysis of olefin metathesis reactions (OMS: olefin metathesis site). The synergy within the active pairs is revealed by studying the coadsorption geometry of the olefin substrates over the active pairs by synchrotron X-ray and neutron powder diffraction. It is shown that the BAS not only facilitates olefin adsorption but also aligns the olefin molecule to the Re OMS for efficient intermediate formation. Consequently, for the cross-metathesis of ethene and trans-2-butene to propene, this catalyst shows high activity under mild reaction conditions without observable deactivation. The catalyst outperforms not only traditional ReOx-based catalysts but also the best industrially applicable WOx-based catalyst thus far that we discovered previously. The concept of using two isolated active sites of different functionalities within atomic proximity in a confined cavity can provide opportunities for designing synergistically catalytic materials.
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Mar 2021
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B18-Core EXAFS
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Diamond Proposal Number(s):
[20856]
Open Access
Abstract: The catalytic synthesis of NH3 from the thermodynamically challenging N2 reduction reaction under mild conditions is currently a significant problem for scientists. Accordingly, herein, we report the development of a nitrogenase-inspired inorganic-based chalcogenide system for the efficient electrochemical conversion of N2 to NH3, which is comprised of the basic structure of [Fe–S2–Mo]. This material showed high activity of 8.7 mgNH3 mgFe−1 h−1 (24 μgNH3 cm−2 h−1) with an excellent faradaic efficiency of 27% for the conversion of N2 to NH3 in aqueous medium. It was demonstrated that the Fe1 single atom on [Fe–S2–Mo] under the optimal negative potential favors the reduction of N2 to NH3 over the competitive proton reduction to H2. Operando X-ray absorption and simulations combined with theoretical DFT calculations provided the first and important insights on the particular electron-mediating and catalytic roles of the [Fe–S2–Mo] motifs and Fe1, respectively, on this two-dimensional (2D) molecular layer slab.
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Jan 2021
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I11-High Resolution Powder Diffraction
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Wei-Che
Lin
,
Simson
Wu
,
Guangchao
Li
,
Ping-Luen
Ho
,
Yichen
Ye
,
Pu
Zhao
,
Sarah
Day
,
Chiu
Tang
,
Wei
Chen
,
Anmin
Zheng
,
Benedict T. W.
Lo
,
Shik Chi Edman
Tsang
Diamond Proposal Number(s):
[16358]
Open Access
Abstract: Catalytic conversion of methanol to aromatics and hydrocarbons is regarded as a key alternative technology to oil processing. Although the inclusion of foreign metal species in H-ZSM-5 containing Brønsted acid site (BAS) is commonly found to enhance product yields, the nature of catalytically active sites and the rationalization for catalytic performance still remain obscure. Herein, by acquiring comparable structural parameters by both X-ray and neutron powder diffractions over a number of metal-modified ZSM-5 zeolites, it is demonstrated for the first time that active pairs of metal site-BAS within molecular distance is created when single and isolated transition metal cation is ion-exchanged with the zeolites. According to our DFT model, this could lead to the initial heterolytic cleavage of small molecules such as water and methanol by the pair with subsequent reactions to form products at high selectivity as that observed experimentally. It may account for their active and selective catalytic routes of small molecule activations.
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Oct 2020
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I11-High Resolution Powder Diffraction
I15-1-X-ray Pair Distribution Function (XPDF)
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Tianyi
Chen
,
Ieuan
Ellis
,
Thomas
Hooper
,
Emanuela
Liberti
,
Lin
Ye
,
Tsz Woon Benedict
Lo
,
Colum
O'Leary
,
Alexandra A.
Sheader
,
Gerardo T.
Martinez
,
Lewys
Jones
,
Ping-Luen
Ho
,
Pu
Zhao
,
James
Cookson
,
Peter T
Bishop
,
Philip A.
Chater
,
John V.
Hanna
,
Peter D.
Nellist
,
Shik Chi Edman
Tsang
Diamond Proposal Number(s):
[15452]
Abstract: It is well established that the inclusion of small atomic species such as boron (B) in powder metal catalysts can subtly modify catalytic properties, and the associated changes in the metal lattice implies that the B atoms are located in the interstitial sites. However, there is no compelling evidence for the occurrence of interstitial B atoms, and there is a concomitant lack of detailed structural information describing the nature of this occupancy and its effects on the metal host. In this work, we use an innovative combination of high-resolution 11B magic-angle-spinning (MAS) and 105Pd static solid state NMR nuclear magnetic resonance (NMR), synchrotron X-ray diffraction (SXRD), in-situ X-ray pair distribution function (XPDF), scanning transmission electron microscopy-annular dark field imaging (STEM-ADF), electron ptychography and electron energy loss spectroscopy (EELS) to investigate the B atom positions, properties and structural modifications to the palladium lattice of an industrial type interstitial boron doped palladium nanoparticle catalyst system (Pd-intB/C NPs). In this study we report that upon B incorporation into the Pd lattice, the overall face centered cubic (FCC) lattice is maintained, however short range disorder is introduced. The 105Pd static solid-state NMR illustrates how different types (and levels) of structural strain and disorder are introduced in the nanoparticle history. These structural distortions can lead to the appearance of small amounts of local hexagonal close packed (HCP) structured material in localized regions. The short range lattice tailoring of the Pd framework to accommodate interstitial B dopants in the octahedral sites of the distorted FCC structure can be imaged by electron ptychography. This study describes new toolsets that enables the characterization of industrial metal nanocatalysts across length scales from macro-analysis to micro-analysis, which gives important guidance to structure-activity relationship of the system.
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Nov 2019
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