Your search keyword '"Tsang SCE"' showing total 70 results

1. Spatial Differentiation of Aluminium Siting by the Single-Atom Adsorption Sites in Zeolite by Electron Microscopy

Author

Ho, P-LB, Foo, C, Lin, W-C, Tsang, SCE, and Nellist, PD

Subjects

Instrumentation

Published

2022

2. Unusual Catalytic Properties of High-Energetic-Facet Polar Metal Oxides

Author

Li, Y and Tsang, SCE

Subjects

Materials science, 010405 organic chemistry, Oxide, General Medicine, General Chemistry, 010402 general chemistry, Heterogeneous catalysis, 01 natural sciences, Surface energy, 0104 chemical sciences, Characterization (materials science), Catalysis, chemistry.chemical_compound, Adsorption, chemistry, Chemical physics, Facet, Surface reconstruction

Abstract

Conspectus Heterogeneous catalysis is an area of great importance not only in chemical industries but also in energy conversion and environmental technologies. It is well-established that the specific surface morphology and structure of solid catalysts exert remarkable effects on catalytic performances, since most physical and chemical processes take place on the surface during catalytic reactions. Different from the widely studied faceted metallic nanoparticles, metal oxides give more complicated structures and surface features. Great progress has been achieved in controlling the shape and exposed facets of transition metal oxides during nanocrystal growth, usually by using surface-directing agents (SDAs). However, the effects of exposed facets remain controversial among researchers. It should be noted that high-energetic facets, especially polar facets, tend to lower their surface energy via different relaxation processes, such as surface reconstruction, redox change, adsorption of countercharged species, etc. These processes can subsequently lead to surface defect formation and break the surface stoichiometry, and the resulting changes in electronic configurations and charge migration properties all play important roles in heterogeneous catalysis. Because different materials prefer different relaxation methods, various surface features are created, and different techniques are required to investigate the different features from facet to facet. Conventional characterization techniques such as X-ray diffraction, X-ray photoelectron spectroscopy, transmission electron microscopy, etc. appear to be insufficient to elucidate the underlying principles of the facet effects. Consequently, an increasing number of novel techniques have been developed to differentiate the surface features, enabling greater understanding of the effects of facets on heterogeneous catalysis. In this Account, on the basis of previous studies by our own group, we will focus on the effects of tailored facets on heterogeneous catalysis introduced by engineered simple binary metal oxide nanomaterials primarily with exposed polar facets, in combination with detailed surface studies using a range of new characterization techniques. As a result, fundamental principles of the effects of facets are elucidated, and the structure–activity correlations are demonstrated. The surface features introduced by different relaxation processes are also investigated using a range of characterization techniques. For example, electron paramagnetic resonance spectroscopy is used to detect the oxygen vacancies, while probe-assisted solid-state NMR spectroscopy is shown to be facet-sensitive and able to evaluate the surface acidity. It is also shown that such different features influence the heterogeneous catalytic performances in different ways. With the help of first-principles density functional theory calculations, unique properties of the faceted metal oxides are discussed and unraveled. Besides, other materials such as transition metal chalcogenides and layered double hydroxides are also briefly discussed with regard to their application in facet-dependent catalysis studies.

Published

2020

3. Achieving Ultrahigh-Rate Planar and Dendrite-Free Zinc Electroplating for Aqueous Zinc Battery Anodes

Author

Pu, SD, Gong, C, Tang, YT, Ning, Z, Liu, J, Zhang, S, Yuan, Y, Melvin, D, Yang, S, Pi, L, Marie, J-J, Hu, B, Jenkins, M, Li, Z, Liu, B, Tsang, SCE, Marrow, TJ, Reed, RC, Gao, X, Bruce, PG, and Robertson, AW

Subjects

Mechanics of Materials, TK, Mechanical Engineering, QD, General Materials Science, TS

Abstract

Despite being one of the most promising candidates for grid-level energy storage, practical aqueous zinc batteries are limited by dendrite formation, which leads to significantly compromised safety and cycling performance. In this study, by using single-crystal Zn-metal anodes, reversible electrodeposition of planar Zn with a high capacity of 8 mAh cm−2 can be achieved at an unprecedentedly high current density of 200 mA cm−2. This dendrite-free electrode is well maintained even after prolonged cycling (>1200 cycles at 50 mA cm−2). Such excellent electrochemical performance is due to single-crystal Zn suppressing the major sources of defect generation during electroplating and heavily favoring planar deposition morphologies. As so few defect sites form, including those that would normally be found along grain boundaries or to accommodate lattice mismatch, there is little opportunity for dendritic structures to nucleate, even under extreme plating rates. This scarcity of defects is in part due to perfect atomic-stitching between merging Zn islands, ensuring no defective shallow-angle grain boundaries are formed and thus removing a significant source of non-planar Zn nucleation. It is demonstrated that an ideal high-rate Zn anode should offer perfect lattice matching as this facilitates planar epitaxial Zn growth and minimizes the formation of any defective regions.

Published

2022

4. Hydrogen-Catalyzed Acid Transformation for the Hydration of Alkenes and Epoxy Alkanes over Co-N Frustrated Lewis Pair Surfaces

Author

Deng, Q, Li, X, Gao, R, Wang, J, Zeng, Z, Zou, J-J, Deng, S, and Tsang, SCE

Subjects

Colloid and Surface Chemistry, General Chemistry, Biochemistry, Catalysis

Abstract

Hydrogen (H2) is widely used as a reductant for many hydrogenation reactions; however, it has not been recognized as a catalyst for the acid transformation of active sites on solid surface. Here, we report the H2-promoted hydration of alkenes (such as styrenes and cyclic alkenes) and epoxy alkanes over single-atom Co-dispersed nitrogen-doped carbon (Co-NC) via a transformation mechanism of acid–base sites. Specifically, the specific catalytic activity and selectivity of Co-NC are superior to those of classical solid acids (acidic zeolites and resins) per micromole of acid, whereas the hydration catalysis does not take place under a nitrogen atmosphere. Detailed investigations indicate that H2can be heterolyzed on the Co–N bond to form Hδ−–Co–N–Hδ+and then be converted into OHδ−–Co–N–Hδ+accompanied by H2generation via a H2O-mediated path, which significantly reduces the activation energy for hydration reactions. This work not only provides a novel catalytic method for hydration reactions but also removes the conceptual barriers between hydrogenation and acid catalysis.

Published

2021

5. Materials for electrochemical ammonia synthesis

Author

McPherson, IJ, Sudmeier, T, Fellowes, J, and Tsang, SCE

Subjects

Inorganic Chemistry, Ammonia production, Materials science, 010405 organic chemistry, Carbon footprint, Nanotechnology, 010402 general chemistry, Electrochemistry, 01 natural sciences, Energy storage, 0104 chemical sciences

Abstract

Direct electrochemical synthesis of ammonia is proposed as a means of reducing the carbon footprint of the fertiliser industry, as well as providing new opportunities for carbon-free liquid energy storage. We review the current status of research into materials for electrochemical ammonia synthesis and evaluate the reported rates and efficiencies in terms of recent US Department of Energy targets. Surprisingly, development of electrocatalysts has only recently received much attention, and despite a number of promising rates, the target values remain distant. A number of theoretical studies suggest a range of candidate materials yet to be explored.

Published

2019

6. ANYL 111-Development of a novel electrochemical DNA-sensor

Author

Shrestha, S, Mills, C, and Tsang, SCE

Published

2016

7. New nanocatalysts for cleaner energy provisions

Author

Tsang, SCE and Wu, C-T

Published

2016

8. Charge dynamics at heterojunctions for PbS/ZnO colloidal quantum dot solar cells probed with time-resolved surface photovoltage spectroscopy

Author

Spencer, BF, Leontiadou, M, Clark, PCJ, Williamson, AI, Silly, MG, Sirotti, F, Fairclough, SM, Tsang, SCE, Neo, DCJ, Assender, HE, Watt, AAR, and Flavell, WR

Abstract

Time-resolved laser-pump X-ray-photoemission-probe spectroscopy of a ZnO (101 ⎯ ⎯ 0 \ud 101¯0\ud ) substrate with and without PbS quantum dots (QDs) chemically linked to the surface is performed, using laser photon energies resonant with and below the band gap energy of the substrate (λ = 372 and 640 nm, hν = 3.33 and 1.94 eV). Charge injection from the photoexcited QDs to ZnO is demonstrated through the change in the surface photovoltage of the ZnO substrate observed when the heterojunction is illuminated with 1.94 eV radiation. The measured carrier dynamics are limited by the persistent photoconductivity of ZnO, giving dark carrier lifetimes of the order of 200 μs in a depletion layer at the interface. The chemical specificity of soft X-rays is used to separately measure the charge dynamics in the quantum dots and the substrate, yielding evidence that the depletion region at the interface extends into the PbS QD layer.

9. Heterogeneous copper-based catalysts for low-temperature methanol steam reforming

Author

Vickery, W and Tsang, SCE

Abstract

This thesis concerns the development of a new class of methanol steam reforming (MSR) catalyst precursors. The work aims to facilitate advances in on-board, MSR-powered proton exchange membrane fuel cell technology by producing catalysts with high H2 production rates and optimal H2:CO selectivity. CuZn-based layered double hydroxides (LDHs) were synthesised and exfoliated using a novel, simple and scalable aqueous miscible organic solvent method to yield catalyst precursors with high surface areas and copper dispersions. This is the first time such methods were used in the preparation of MSR catalysts; a CuZnAl-LDH precursor achieved a BET surface area and copper dispersion percentage of 252 m2.g−1 and 53.9 %, respectively. It was found that an optimal content of Ce doped into the catalysts suppressed CO production. Many of the catalysts in this work produced a higher H2:CO mol ratio than the previous best recorded ratio in literature, 3000 molH2:molCO, under conditions that favoured higher reverse water gas shift activity; specifically, 27 % less water content and a 70 % lower weight hourly space velocity (WHSV). Notably, a CuZnGaCe catalyst from this work produced 4721 molH2:molCO, with an activity of 14.4 µmolH2.s−1.gcat, at 180 °C using a 1.1:1 mol ratio of water/methanol reactants and a 2.03 h−1 WHSV. Additionally, this work investigated the previously unsolved structure of lanthanide-doped LDHs with a wide variety of techniques including high resolution-EDX, Ce L3 edge XAS and DFT analysis; this allowed the structure to be proposed. XAS was also used to analyse catalyst samples from different stages of water gas shift reactions to gather insight on how the catalysts improved selectivity.

Published

2022

10. Synthesis and characterization of inorganic nanomaterials for applications in energy storage and catalysis

Author

Kulhavý, J and Tsang, SCE

Subjects

Heterogeneous catalysis, Electrochemistry, Nanoparticles, Nanostructured materials, Chemistry, Inorganic

Abstract

Inorganic nanomaterials are defined as materials with one or more dimension within 1 – 100 nm range. These materials possess unique optical, electronic, thermo-physical, physicochemical and mechanical properties, and represent intensively explored, studied and sought-after commodities for a large variety of applications and manufacturing processes. Heterogeneous catalysts are vital for many industrial processes and often take advantage of the unique reactivity properties of nanomaterials, while battery electrode materials composed of nanomaterials are explored to solve current limitations with higher power densities via stable rapid ion and electron transport, and with high energy density via maximization of the charge storage capability. This thesis provides an insight into synthetic methods, detailed characterization and properties study, and exemplary applications of engineered 2D MoS2 nanomaterials in Li and Na ion batteries, palladium nanoparticles supported on 2D MoS2 nanosheets as heterogeneous catalysts in Suzuki and Heck C-C coupling and 1-pentyne hydrogenation reactions and sulphate functionalized titanium oxide nanoparticles as solid superacid catalysts in the esterification reaction of levulinic acid and pyruvaldehyde Cannizzaro reactions.

Published

2022

11. Structural and dynamic studies of Zr-based metal-organic frameworks toward external stimuli

Author

Yoskamtorn, Tatchamapan and Tsang, SCE

Subjects

Neutrons--Diffraction, Quasielastic neutron scattering, Functional materials, Porous materials, Chemistry, Inorganic, Neutrons--Inelastic scattering

Abstract

Advanced studies of structures and dynamics of functional materials based on metal-organic frameworks (MOFs) showing exceptional stimuli-driven properties is of strong current interest for the design of next-generation smart materials, especially for sorption-based applications such as gas storage, energy storage, controlled drug delivery, and molecular sensing, to name but a few. State-of-the-art diffraction and spectroscopy in conjunction with theoretical calculations are one of the most powerful approaches to achieve these detailed analyses at a molecular level. This thesis aims to study mechanistic aspects of stimuli-responsive behaviours responsible for a distinctive stepwise ammonia (NH3) adsorption in the defect-rich Zr-based metal-organic frameworks (MOFs), namely UiO-67 and its isostructural UiO-bpydc, both experimentally and computationally. In Chapter 3, high-resolution neutron and synchrotron diffractions along with Rietveld refinement and density functional theory (DFT) calculations have been used to characterise the binding domains and the interactions of NH3/ND3 with defect-rich UiO-67 and UiO-bpydc containing biphenyl dicarboxylate and bipyridine dicarboxylate linkers, respectively. The results establish that the dramatic alteration of stepwise adsorption processes is closely associated with hydrogen bonding network between NH3/ND3 and the frameworks at the disordered/defective trigonal and lozenge pore windows of the materials without significant change in pore volume and unit cell parameters. Specifically, UiO-bpydc is possible to make stronger and more extensive hydrogen bonding using pyridine sites of the linker than in UiO-67. These molecular controls lead to stimulus-tailoring properties such as gate-controlled porosity by dynamic linker flipping, disorder, and structural rigidity which are further confirmed by temperature-dependence of in situ structural analyses accompanied with guest-induced rotational motions of the organic linkers studied by DFT in Chapter 4. To get deeper insights into the interesting NH3-induced stepwise adsorption, the dynamic features of the MOF-NH3 systems have been further investigated by using advanced inelastic neutron scattering (INS), quasi-elastic neutron scattering (QENS) in conjunction with theoretical calculations. Guest-induced linker stiffening reflected by the suppression of lattice motions of the host frameworks upon NH3 adsorption is achieved, which exhibits greater effect in the UiO-bpydc case. More excitingly, analysis of INS difference spectra reveals heterogeneous dynamics of the trapped NH3 depending on MOF functionality and gas loading. For the UiO-67, the well-ordered NH3 molecules primarily adsorbed at μ3-OH have more feasibility to undergo progressive interactions with the incoming NH3 molecules, signifying its more accessible porous structure for NH3 inclusion due to the lack of guest-stimulated pore blocking conversely observed in the UiO-bpydc. QENS study elucidates negligible mobility of NH3 in both MOFs at the lowest dosage, indicative of the similar localised diffusion caused by strongly bound NH3 at the μ3-OH sites of the hosts. On the other hand, the NH3 diffusivities in these frameworks become distinct at higher NH3 uptake where the stepped adsorption occurs. This observation points toward the confined NH3 molecules experiencing a diversity of either pore environments or host-guest interactions.

Published

2021

12. Simulation and experimental results of an absorbent-enhanced ammonia synthesis reactor

Author

Qi, W, Banares-Alcantara, R, and Tsang, SCE

Subjects

Ammonia

Abstract

This thesis investigates the design and performance of absorbent-enhanced ammonia synthesis reactors. The per-pass conversion of ammonia can be improved by the sequencing of ammonia synthesis catalyst and ammonia-selective absorbent beds in the reactor. A new perspective includes adjacent coupling and multi-bed coupled absorptive reactors which contributes to the exciting area of ammonia synthesis improvement. This type of reactors enable operation under conditions milder than those used in a traditional Haber-Bosch reactor. As part of the work a novel Ru catalyst with polar metallic oxide support was developed to meet the requirements of mild operating conditions of the absorptive reactor. An experimental unit was built to perform the synthesis of ammonia in a fixed-bed absorptive reactor, and an increased per-pass conversion was observed from experimental data. Mathematical models were also developed to provide insights into the reasons for the conversion improvement in the absorptive reactor. Our simulations of these two kinds of absorption-enhanced ammonia synthesis reactors contribute to their understanding and confirm the enhancement of their per-pass conversion. A preliminary mathematical model study of the adjacent coupling absorptive reactor was carried out first in which the influence of absorption on the per-pass ammonia conversion was linked to a hypothetical recycle stream. Based on the result of this preliminary model, a more detailed transient backflow cell model was developed to simulate the behaviour of the adjacent coupling absorptive reactor. Given the complexity of the reacting fluid through the fixed bed, a computational fluid dynamics simulation via ANSYS Fluent was also generated and resulted in similar results to those of the transient backflow cell model. On this basis, an improved absorptive reactor, i.e. the multi-bed absorptive reactor, was proposed and modelled in Fluent, achieving close to 100% per-pass conversion. This research improved the per-pass conversion of ammonia synthesis reactors and enabled milder operating conditions for process. Furthermore, a theoretical framework was provided through mathematical modelling for optimisation purposes.

Published

2021

13. Sugar conversion to hydroxymethylfurfural and aromatics over niobium oxides and modified zeolites

Author

Kreissl, HT, O'Hare, D, and Tsang, SCE

Abstract

Research in the field of renewable energies is becoming ever more important due to the depletion of fossil fuels and increasing environmental concerns. The upgrading of biomass to commodity and fine chemicals in order to substitute conventional fossil-fuel derived products is a major topic in the area, particularly the upgrading of sugars as the main biomass component. Glucose derived from cellulose is the most abundant sugar and its acid catalysed dehydration yields the platform molecule hydroxymethylfurfural (HMF), a promising precursor for plastics, solvents, fuels and fine chemicals. In this work the conversion of sugars to HMF is studied in water over niobium oxides as solid acid catalysts, presenting an environmentally- and separation-friendly conversion route. An emphasis is put on the reaction mechanistic details and the analysis of catalyst structure in relation to acidity and catalytic performance, as these are key factors in the development of targeted synthesis and improved catalysts. For example, the efficient conversion of glucose to HMF requires the presence of both Lewis acid (LA) and Brønsted acid (BA) sites on the niobium oxides. Large quantities of both LA (exposed Nb centres) and BA (acidic surface hydroxyl) sites are found prominently on the nano-structured niobium oxides compared to their bulk analogues. This results from the large surface areas and structural flexibility of the nano-materials, where LA sites appear to arise from distortions and oxygen defects. Amorphous mesoporous Nb2O5*ub>nH2O shows the best catalytic performance due to the presence of both LA and comparably weak BA sites, where weaker BA sites are formed by protons of terminal surface hydroxyl groups. In addition to sugar conversion to HMF, the conversion of HMF to aromatic hydrocarbons has been addressed, using a two-step reaction route via dimethylfuran (DMF) over modified zeolite catalysts. Although there is room for yield improvements, the significant advantage of this route is the use of ethanol as common solvent and sacrificial reagent for both reaction steps, facilitating the combination into a one-batch-process in the future. Aromatics are important fuel additives and precursors for polymers, resins and solvents and are currently fossil-fuel derived, raising the need for such alternative production pathways.

Published

2018

14. Heterogeneous Frustrated Lewis Pair Catalysts: Rational Structure Design and Mechanistic Elucidation Based on Intrinsic Properties of Supports.

Author

Li J, Li G, and Tsang SCE

Abstract

ConspectusThe discovery of reversible hydrogenation using metal-free phosphoborate species in 2006 marked the official advent of frustrated Lewis pair (FLP) chemistry. This breakthrough revolutionized homogeneous catalysis approaches and paved the way for innovative catalytic strategies. The unique reactivity of FLPs is attributed to the Lewis base (LB) and Lewis acid (LA) sites either in spatial separation or in equilibrium, which actively react with molecules. Since 2010, heterogeneous FLP catalysts have gained increasing attention for their ability to enhance catalytic performance through tailored surface designs and improved recyclability, making them promising for industrial applications. Over the past 5 years, our group has focused on investigating and strategically modifying various types of solid catalysts with FLPs that are unique from classic solid FLPs. We have explored systematic characterization techniques to unravel the underlying mechanisms between the active sites and reactants. Additionally, we have demonstrated the critical role of catalysts' intrinsic electronic and geometric properties in promoting FLP formation and stimulating synergistic effects. The characterization of FLP catalysts has been greatly enhanced by the use of advanced techniques such as synchrotron X-ray diffraction, neutron powder diffraction, X-ray photoelectron spectroscopy, extended X-ray absorption fine structure, elemental mapping in scanning transmission electron microscopy, electron paramagnetic resonance spectroscopy, diffuse-reflectance infrared Fourier transform spectroscopy, and solid-state nuclear magnetic resonance spectroscopy. These techniques have provided deeper insights into the structural and electronic properties of FLP systems for the future design of catalysts.Understanding electron distribution in the overlapping orbitals of LA and LB pairs is essential for inducing FLPs in operando in heterogeneous catalysts through target electron reallocation by external stimuli. For instance, in silicoaluminophosphate-type zeolites with weak orbital overlap, the adsorption of polar gas molecules leads to heterolytic cleavage of the Al δ+ -O δ- bond, creating unquenched LA-LB pairs. In a Ru-doped metal-organic framework, the Ru-N bond can be polarized through metal-ligand charge transfer under light, forming Ru + -N - pairs. This activation of FLP sites from the framework represents a groundbreaking innovation that expands the catalytic potential of existing materials. For catalysts already employing FLP chemistry to dynamically generate products from substrates, a complete mechanistic interpretation requires a thorough examination of the surface electronic properties and the surrounding environment. The hydrogen spillover ability on the Ru-doped FLP surfaces improves conversion efficiency by suppressing hydrogen poisoning at metal sites. In situ H 2 -H 2 O conditions enable the production of organic chemicals with excellent activity and selectivity by creating new bifunctional sites via FLP chemistry. By highlighting the novel FLP systems featuring FLP induction and synergistic effects and the selection of advanced characterization techniques to elucidate reaction mechanisms, we hope that this Account will offer innovative strategies for designing and characterizing FLP chemistry in heterogeneous catalysts to the research community.

Published

2025

15. Atomic locations and adsorbate interactions of Al single and pair sites in H-ZSM-5 zeolite.

Author

Li G, Foo C, Fan R, Zheng M, Wang Q, Chu Y, Li J, Day S, Steadman P, Tang C, Lo TWB, Deng F, and Tsang SCE

Abstract

The distribution of substitutional aluminum (Al) atoms in zeolites affects molecular adsorbate geometry, catalytic activity, and shape and size selectivity. Accurately determining Al positions has been challenging. We used synchrotron resonant soft x-ray diffraction (RSXRD) at multiple energies near the Al K-edge combined with molecular adsorption techniques to precisely locate "single Al" and "Al pairs" in a commercial H-ZSM-5 zeolite. This analysis depicts three distinct Al tetrahedral (T) sites: T8, T6, and T4. A combined suite of characterizations, including ammonia temperature-dependent desorption, neutron powder diffraction, solid-state nuclear magnetic resonance spectroscopy, and density functional theory calculations, reveal isolated ammonia adsorption on T8 as "single Al" in the straight channel and bridged ammonia adsorption on T6 and T4 as an "Al pair" (Al T6 -O-Si T5 -O-Al T4 ) in the straight-sinusoidal intersection.

Published

2025

16. Heterogeneous catalysis strategies for polyolefin plastic upcycling: co-reactant-assisted and direct transformation under mild conditions.

Author

Wang H, Huang S, and Tsang SCE

Abstract

The large-scale production and inadequate disposal of polyolefin (PO) plastics pose significant environmental challenges. Traditional recycling methods are energy-intensive and often ineffective, prompting a need for more sustainable approaches. In recent years, catalytic upcycling under mild conditions has emerged as a promising strategy to transform PO plastics into valuable products. Co-reactants such as hydrogen, short-chain alkanes or alkenes, oxygen, and CO 2 play a crucial role in driving these transformations, influencing reaction mechanisms and broadening the range of possible products. This review categorizes recent advancements in PO plastic upcycling based on the type of co-reactant employed and compares these with direct, co-reactant-free processes. Despite these advances, challenges remain in improving catalytic stability, product selectivity, and overcoming diffusion limitations in viscous plastic feedstocks. This review underscores the catalytic chemistry underpinning the development of efficient PO plastic upcycling processes with co-reactants, offering insights into future directions for sustainable plastic chemical management.

Published

2025

17. Black titanium oxide: synthesis, modification, characterization, physiochemical properties, and emerging applications for energy conversion and storage, and environmental sustainability.

Author

Hou X, Li Y, Zhang H, Lund PD, Kwan J, and Tsang SCE

Abstract

Since its advent in 2011, black titanium oxide (B-TiO x ) has garnered significant attention due to its exceptional optical characteristics, notably its enhanced absorption spectrum ranging from 200 to 2000 nm, in stark contrast to its unmodified counterpart. The escalating urgency to address global climate change has spurred intensified research into this material for sustainable hydrogen production through thermal, photocatalytic, electrocatalytic, or hybrid water-splitting techniques. The rapid advancements in this dynamic field necessitate a comprehensive update. In this review, we endeavor to provide a detailed examination and forward-looking insights into the captivating attributes, synthesis methods, modifications, and characterizations of B-TiO x , as well as a nuanced understanding of its physicochemical properties. We place particular emphasis on the potential integration of B-TiO x into solar and electrochemical energy systems, highlighting its applications in green hydrogen generation, CO 2 reduction, and supercapacitor technology, among others. Recent breakthroughs in the structure-property relationship of B-TiO x and its applications, grounded in both theoretical and empirical studies, are underscored. Additionally, we will address the challenges of scaling up B-TiO x production, its long-term stability, and economic viability to align with ambitious future objectives.

Published

2024

18. Active nitrogen sites on nitrogen doped carbon for highly efficient associative ammonia decomposition.

Author

Ye D, Leung KC, Niu W, Duan M, Li J, Ho PL, Szalay D, Wu TS, Soo YL, Wu S, and Tsang SCE

Abstract

Nitrogen doped carbon materials have been studied as catalyst support for ammonia decomposition. There are 4 different types of nitrogen environments (graphitic, pyrrolic, pyridinic and nitrogen oxide) on the amorphous support identified. In this paper, we report a 5%Ru on MgCO 3 pre-treated nitrogen doped carbon catalyst with high content of edge nitrogen-containing sites which displays an ammonia conversion rate of over 90% at 500°C and WHSV = 30,000 mL g cat -1 h -1 . It also gives an impressive hydrogen production rate of 31.3 mmol/(min g cat ) with low apparent activation energy of 43 kJ mol -1 . Fundamental studies indicate that the distinct average Ru-N 4 coordination site on edge regions is responsible for such high catalytic activity. Ammonia is stepwise decomposed via a Ru-N(H)-N(H)-Ru intermediate. This associative mechanism circumvents the direct cleavage of energetic surface nitrogen from metal to form N 2 hence lowering the activation barrier for the decomposition over this catalyst., Competing Interests: The authors declare no competing interests., (© 2024 Published by Elsevier Inc.)

Published

2024

19. Stabilization of Ni-containing Keggin-type polyoxometalates with variable oxidation states as novel catalysts for electrochemical water oxidation.

Author

Li X, Ng BKY, Ho PL, Jia C, Shang J, Yoskamtorn T, Pan X, Li Y, Li G, Wu TS, Soo YL, He H, Yue B, and Tsang SCE

Abstract

The development of new recyclable and inexpensive electrochemically active species for water oxidation catalysis is the most crucial step for future utilization of renewables. Particularly, transition metal complexes containing internal multiple, cooperative metal centers to couple with redox catalysts in the inorganic Keggin-type polyoxometalate (POM) framework at high potential or under extreme pH conditions would be promising candidates. However, most reported Ni-containing POMs have been highly unstable towards hydrolytic decomposition, which precludes them from application as water oxidation catalysts (WOCs). Here, we have prepared new tri-Ni-containing POMs with variable oxidation states by charge tailored synthetic strategies for the first time and developed them as recyclable POMs for water oxidation catalysts. In addition, by implanting corresponding POM anions into the positively charged MIL-101(Cr) metal-organic framework (MOF), the entrapped Ni 2+ /Ni 3+ species can show complete recyclability for water oxidation catalysis without encountering uncontrolled hydrolysis of the POM framework. As a result, a low onset potential of approximately 1.46 V vs. NHE for water oxidation with stable WOC performance is recorded. Based on this study, rational design and stabilization of other POM-electrocatalysts containing different multiple transition metal centres could be made possible., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published

2024

20. Electric-field-assisted proton coupling enhanced oxygen evolution reaction.

Author

Pan X, Yan M, Liu Q, Zhou X, Liao X, Sun C, Zhu J, McAleese C, Couture P, Sharpe MK, Smith R, Peng N, England J, Tsang SCE, Zhao Y, and Mai L

Abstract

The discovery of Mn-Ca complex in photosystem II stimulates research of manganese-based catalysts for oxygen evolution reaction (OER). However, conventional chemical strategies face challenges in regulating the four electron-proton processes of OER. Herein, we investigate alpha-manganese dioxide (α-MnO 2 ) with typical Mn IV -O-Mn III -H x O motifs as a model for adjusting proton coupling. We reveal that pre-equilibrium proton-coupled redox transition provides an adjustable energy profile for OER, paving the way for in-situ enhancing proton coupling through a new "reagent"- external electric field. Based on the α-MnO 2 single-nanowire device, gate voltage induces a 4-fold increase in OER current density at 1.7 V versus reversible hydrogen electrode. Moreover, the proof-of-principle external electric field-assisted flow cell for water splitting demonstrates a 34% increase in current density and a 44.7 mW/cm² increase in net output power. These findings indicate an in-depth understanding of the role of proton-incorporated redox transition and develop practical approach for high-efficiency electrocatalysis., (© 2024. The Author(s).)

Published

2024

21. Synthesis of core@shell catalysts guided by Tammann temperature.

Author

Xiong P, Xu Z, Wu TS, Yang T, Lei Q, Li J, Li G, Yang M, Soo YL, Bennett RD, Lau SP, Tsang SCE, Zhu Y, and Li MM

Abstract

Designing high-performance thermal catalysts with stable catalytic sites is an important challenge. Conventional wisdom holds that strong metal-support interactions can benefit the catalyst performance, but there is a knowledge gap in generalizing this effect across different metals. Here, we have successfully developed a generalizable strong metal-support interaction strategy guided by Tammann temperatures of materials, enabling functional oxide encapsulation of transition metal nanocatalysts. As an illustrative example, Co@BaAl 2 O 4 core@shell is synthesized and tracked in real-time through in-situ microscopy and spectroscopy, revealing an unconventional strong metal-support interaction encapsulation mechanism. Notably, Co@BaAl 2 O 4 exhibits exceptional activity relative to previously reported core@shell catalysts, displaying excellent long-term stability during high-temperature chemical reactions and overcoming the durability and reusability limitations of conventional supported catalysts. This pioneering design and widely applicable approach has been validated to guide the encapsulation of various transition metal nanoparticles for environmental tolerance functionalities, offering great potential to advance energy, catalysis, and environmental fields., (© 2024. The Author(s).)

Published

2024

22. Photo-Induced Active Lewis Acid-Base Pairs in a Metal-Organic Framework for H 2 Activation.

Author

Ng BKY, Zhou ZJ, Liu TT, Yoskamtorn T, Li G, Wu TS, Soo YL, Wu XP, and Tsang SCE

Abstract

The establishment of active sites as the frustrated Lewis pair (FLP) has recently attracted much attention ranging from homogeneous to heterogeneous systems in the field of catalysis. Their unquenched reactivity of Lewis acid and base pairs in close proximity that are unable to form stable adducts has been shown to activate small molecules such as dihydrogen heterolytically. Herein, we show that grafted Ru metal-organic framework-based catalysts prepared via N-containing linkers are rather catalytically inactive for H 2 activation despite the application of elevated temperatures. However, upon light illumination, charge polarization of the anchored Ru bipyridine complex can form a transient Lewis acid-base pair, Ru + -N - via metal-to-ligand charge transfer, as confirmed by time-dependent density functional theory (TDDFT) calculations to carry out effective H 2 -D 2 exchange. FTIR and 2-D NMR endorse the formation of such reactive intermediate(s) upon light irradiation.

Published

2023

23. Core-shell silica@Cu x ZnAl LDH catalysts for efficient CO 2 hydrogenation to methanol.

Author

Lyu M, Zheng J, Coulthard C, Ren J, Zhao Y, Tsang SCE, Chen C, and O'Hare D

Abstract

The efficient production of methanol by reduction of CO 2 using green hydrogen is a promising strategy from both a green chemistry and a carbon net zero perspective. Herein, we report the synthesis of well-dispersed core-shell catalyst precursors using silica@Cu x ZnAl-LDHs that can convert CO 2 to methanol. The catalyst precursors can be formed using either a commercially available silica (ES757) or a mesoporous silica ( e.g. MCM-48). These hybrid materials show significantly enhanced catalytic performance compared to the equivalent unsupported Cu x ZnAl LDH precursor. Space-time yields of up to 0.7 g MeOH g cat -1 h -1 under mild operating conditions were observed., Competing Interests: The authors declare no competing financial interests., (This journal is © The Royal Society of Chemistry.)

Published

2023

24. Alternative routes to NH 3 and its application: general discussion.

Author

Catlow CRA, El-Kadi J, Guan Y, Hargreaves JSJ, Holland PL, Hosono H, Isaacs M, Kaur M, Kobayashi Y, MacFarlane DR, Mishra V, Ntola P, Safeer N K M, Shylin SI, Siahrostami S, Sievers C, Singh DL, Torrente Murciano L, Tort R, Tsang SCE, Uner D, Vincent KA, Wang Q, and Yusuf L

Published

2023

25. Metal-loaded zeolites in ammonia decomposition catalysis.

Author

Leung KC, Tan E, Li G, Ng BKY, Ho PL, Lebedev K, and Tsang SCE

Abstract

The viability of using ammonia as a hydrogen storage vector is contingent on the development of catalytic systems active for ammonia decomposition at low temperatures. Zeolite-supported metal catalysts, unlike systems based on supports like MgO or carbon nanotubes (CNTs), are crystalline and lend themselves to analytic techniques like synchrotron X-ray powder diffraction (SXRD) and Rietveld refinement, allowing precise characterisation of catalytic active sites, and therefore mechanistic elucidation. This study focuses on characterising and optimising novel zeolite-supported Ru catalysts for ammonia decomposition, with a focus on the effects of N-substitution on catalyst structure and activity. Characterisation focuses on an unsubstituted and N-substituted Ru-zeolite Y pair with NMR, FTIR, TEM, XRD, XAS, ICP, and BET, demonstrating the successful incorporation of N into the zeolite framework and an enhancement in metal dispersion upon N-substitution. A series of 18 monometallic and bimetallic catalysts is then synthesised on X and USY supports and screened for catalytic activity. Ru is identified as the most active metal for ammonia decomposition. Observed trends suggest catalyst dispersion can be increased with substantially lower metal loadings, and in particular via the formation of stably anchored oligonuclear metal clusters within the zeolite framework, as opposed to much larger nanoparticles (NPs) on its exterior, following N-substitution of the framework. DFT modelling proposes a prismatic Ru 6 N 6 cluster fitted to XAS data. High-activity catalyst Ru-β (N) 2.4% demonstrates comparable or better ammonia conversion by Ru wt% than recently reported catalysts in the literature at 450 °C and 30 000 WHSV.

Published

2023

26. Confined Ru Sites in a 13X Zeolite for Ultrahigh H 2 Production from NH 3 Decomposition.

Author

Leung KC, Hong S, Li G, Xing Y, Ng BKY, Ho PL, Ye D, Zhao P, Tan E, Safonova O, Wu TS, Li MM, Mpourmpakis G, and Tsang SCE

Abstract

Catalytic NH 3 synthesis and decomposition offer a new promising way to store and transport renewable energy in the form of NH 3 from remote or offshore sites to industrial plants. To use NH 3 as a hydrogen carrier, it is important to understand the catalytic functionality of NH 3 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 NH 3 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 NH 3 is ruptured heterolytically by the frustrated Lewis pair of Ru δ+ -O δ- 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 NH 3 to regenerate framework Brønsted acid sites that eventually are converted to molecular hydrogen.

Published

2023

27. Exceptional Hydrogen Diffusion Rate over Ru Nanoparticle-Doped Polar MgO(111) Surface.

Author

Yoskamtorn T, Mo J, Chen L, Wu S, Mukhopadhyay S, Hawkins A, Wu XP, and Tsang SCE

Abstract

Hydrogen (H) conductivity on oxide-based materials is crucially important in fuel cells and related catalysis. Here, this work measures the diffusion rate of H generated from Ru nanoparticles loaded on polar MgO(111) facet particles under H 2 at elevated temperatures without moisture and compares it to conventional nonpolar MgO(110) for the first time by in situ quasielastic neutron scattering (QENS). The QENS reveals an exceptional diffusion rate on the polar facet via a proton (H + ) hopping mechanism, which is an order of magnitude superior to that of typical H + -conducting oxides. This work attributes this to the unique atomic arrangement of alternate layers of Mg cations and O anions of the polar MgO(111) where the strong electrostatic field of terminal oxygen anions facilitates protonic migration with a lower degree of local covalency., (© 2023 The Authors. Small Methods published by Wiley-VCH GmbH.)

Published

2023

28. Dispersed surface Ru ensembles on MgO(111) for catalytic ammonia decomposition.

Author

Fang H, Wu S, Ayvali T, Zheng J, Fellowes J, Ho PL, Leung KC, Large A, Held G, Kato R, Suenaga K, Reyes YIA, Thang HV, Chen HT, and Tsang SCE

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 N 2 complexes in solution are required for the stepwise dehydrogenation of ammonia to N 2 /H 2 , 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 (B 5 sites) than isolated sites., (© 2023. The Author(s).)

Published

2023

29. [EMmim][NTf 2 ]-a Novel Ionic Liquid (IL) in Catalytic CO 2 Capture and ILs' Applications.

Author

He X, Gao Y, Shi Y, Zhang X, Liang Z, Zhang R, Song X, Lai Q, Adidharma H, Russell AG, Eddings EG, Fei W, Cheng F, Tsang SCE, Wang J, and Fan M

Abstract

Ionic liquids (ILs) have been used for carbon dioxide (CO 2 ) capture, however, which have never been used as catalysts to accelerate CO 2 capture. The record is broken by a uniquely designed IL, [EMmim][NTf 2 ]. The IL can universally catalyze both CO 2 sorption and desorption of all the chemisorption-based technologies. As demonstrated in monoethanolamine (MEA) based CO 2 capture, even with the addition of only 2000 ppm IL catalyst, the rate of CO 2 desorption-the key to reducing the overall CO 2 capture energy consumption or breaking the bottleneck of the state-of-the-art technologies and Paris Agreement implementation-can be increased by 791% at 85 °C, which makes use of low-temperature waste heat and avoids secondary pollution during CO 2 capture feasible. Furthermore, the catalytic CO 2 capture mechanism is experimentally and theoretically revealed., (© 2022 The Authors. Advanced Science published by Wiley-VCH GmbH.)

Published

2023

30. Chemical looping based ammonia production-A promising pathway for production of the noncarbon fuel.

Author

Lai Q, Cai T, Tsang SCE, Chen X, Ye R, Xu Z, Argyle MD, Ding D, Chen Y, Wang J, Russell AG, Wu Y, Liu J, and Fan M

Subjects

Nitrogen chemistry, Ammonia, Artificial Intelligence

Abstract

Ammonia, primarily made with Haber-Bosch process developed in 1909 and winning two Nobel prizes, is a promising noncarbon fuel for preventing global warming of 1.5 °C above pre-industrial levels. However, the undesired characteristics of the process, including high carbon footprint, necessitate alternative ammonia synthesis methods, and among them is chemical looping ammonia production (CLAP) that uses nitrogen carrier materials and operates at atmospheric pressure with high product selectivity and energy efficiency. To date, neither a systematic review nor a perspective in nitrogen carriers and CLAP has been reported in the critical area. Thus, this work not only assesses the previous results of CLAP but also provides perspectives towards the future of CLAP. It classifies, characterizes, and holistically analyzes the fundamentally different CLAP pathways and discusses the ways of further improving the CLAP performance with the assistance of plasma technology and artificial intelligence (AI)., Competing Interests: Conflict of interest The authors declare that they have no conflict of interest., (Copyright © 2022 Science China Press. Published by Elsevier B.V. All rights reserved.)

Published

2022

31. 2D MOF with Compact Catalytic Sites for the One-pot Synthesis of 2,5-Dimethylfuran from Saccharides via Tandem Catalysis.

Author

Deng Q, Hou X, Zhong Y, Zhu J, Wang J, Cai J, Zeng Z, Zou JJ, Deng S, Yoskamtorn T, and Tsang SCE

Subjects

Catalysis, Catalytic Domain, Lewis Acids, Furans chemistry, Metal-Organic Frameworks

Abstract

One pot synthesis of 2,5-dimethylfuran (2,5-DMF) from saccharides under mild conditions is of importance for the production of biofuel and fine chemicals. However, the synthesis requires a multitude of active sites and suffers from slow kinetics due to poor diffusion in most composite catalysts. Herein, a metal-acid functionalized 2D metal-organic framework (MOF; Pd/NUS-SO 3 H), as an ultrathin nanosheet of 3-4 nm with Lewis acid, Brønsted acid, and metal active sites, was prepared based on the diazo method for acid modification and subsequent metal loading. This new composite catalyst gives substantially higher yields of DMF than all reported catalysts for different saccharides (fructose, glucose, cellobiose, sucrose, and inulins). Characterization suggests that a cascade of reactions including polysaccharide hydrolysis, isomerization, dehydration, and hydrodeoxygenation takes place with rapid molecular interactions., (© 2022 The Authors. Angewandte Chemie International Edition published by Wiley-VCH GmbH.)

Published

2022

32. Thermal Alteration in Adsorption Sites over SAPO-34 Zeolite.

Author

Li G, Yoskamtorn T, Chen W, Foo C, Zheng J, Tang C, Day S, Zheng A, Li MM, and Tsang SCE

Abstract

Zeolites have found tremendous applications in the chemical industry. However, the dynamic nature of their active sites under the flow of adsorbate molecules for adsorption and catalysis is unclear, especially in operando conditions, which could be different from the as-synthesized structures. In the present study, we report a structural transformation of the adsorptive active sites in SAPO-34 zeolite by using acetone as a probe molecule under various temperatures. The combination of solid-state nuclear magnetic resonance, in situ variable-temperature synchrotron X-ray diffraction, and in situ diffuse-reflectance infrared Fourier-transform spectroscopy allow a clear identification and quantification that the chemisorption of acetone can convert the classical Brønsted acid site adsorption mode to an induced Frustrated Lewis Pairs adsorption mode at increasing temperatures. Such facile conversion is also supported by the calculations of ab-initio molecular-dynamics simulations. This work sheds new light on the importance of the dynamic structural alteration of active sites in zeolites with adsorbates at elevated temperatures., (© 2022 The Authors. Angewandte Chemie International Edition published by Wiley-VCH GmbH.)

Published

2022

33. Controlled synthesis of Bi- and tri-nuclear Cu-oxo nanoclusters on metal-organic frameworks and the structure-reactivity correlations.

Author

Xue Q, Ng BKY, Man HW, Wu TS, Soo YL, Li MM, Kawaguchi S, Wong KY, Tsang SCE, Huang B, and Lo TWB

Abstract

Precisely tuning the nuclearity of supported metal nanoclusters is pivotal for designing more superior catalytic systems, but it remains practically challenging. By utilising the chemical and molecular specificity of UiO-66-NH 2 (a Zr-based metal-organic framework), we report the controlled synthesis of supported bi- and trinuclear Cu-oxo nanoclusters on the Zr 6 O 4 nodal centres of UiO-66-NH 2 . We revealed the interplay between the surface structures of the active sites, adsorption configurations, catalytic reactivities and associated reaction energetics of structurally related Cu-based 'single atoms' and bi- and trinuclear species over our model photocatalytic formic acid reforming reaction. This work will offer practical insight that fills the critical knowledge gap in the design and engineering of new-generation atomic and nanocluster catalysts. The precise control of the structure and surface sensitivities is important as it can effectively lead to more reactive and selective catalytic systems. The supported bi- and trinuclear Cu-oxo nanoclusters exhibit notably different catalytic properties compared with the mononuclear 'Cu 1 ' analogue, which provides critical insight for the engineering of more superior catalytic systems., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published

2021

34. Direct Visualization of Substitutional Li Doping in Supported Pt Nanoparticles and Their Ultra-selective Catalytic Hydrogenation Performance.

Author

Chen T, Foo C, Zheng JJW, Fang H, Nellist P, and Tsang SCE

Abstract

It has only recently been established that doping light elements (lithium, boron, and carbon) into supported transition metals can fill interstitial sites, which can be observed by the expanded unit cell. As an example, interstitial lithium ( int Li) can block H filling octahedral interstices of palladium metal lattice, which improves partial hydrogenation of alkynes to alkenes under hydrogen. In contrast, herein, we report int Li is not found in the case of Pt/C. Instead, we observe for the first time a direct 'substitution' of Pt with substitutional lithium ( sub Li) in alternating atomic columns using scanning transmission electron microscopy-annular dark field (STEM-ADF). This ordered substitutional doping results in a contraction of the unit cell as shown by high-quality synchrotron X-ray diffraction (SXRD). The electron donation of d-band of Pt without higher orbital hybridizations by sub Li offers an alternative way for ultra-selectivity in catalytic hydrogenation of carbonyl compounds by suppressing the facile CO bond breakage that would form alcohols., (© 2021 Wiley-VCH GmbH.)

Published

2021

35. Correction to "High Loading of Transition Metal Single Atoms on Chalcogenide Catalysts".

Author

Zheng J, Lebedev K, Wu S, Huang C, Ayvalı T, Wu TS, Li Y, Ho PL, Soo YL, Kirkland A, and Tsang SCE

Published

2021

36. Rapid Interchangeable Hydrogen, Hydride, and Proton Species at the Interface of Transition Metal Atom on Oxide Surface.

Author

Wu S, Tseng KY, Kato R, Wu TS, Large A, Peng YK, Xiang W, Fang H, Mo J, Wilkinson I, Soo YL, Held G, Suenaga K, Li T, Chen HT, and Tsang SCE

Abstract

Hydrogen spillover is the phenomenon where a hydrogen atom, generated from the dissociative chemisorption of dihydrogen on the surface of a metal species, migrates from the metal to the catalytic support. This phenomenon is regarded as a promising avenue for hydrogen storage, yet the atomic mechanism for how the hydrogen atom can be transferred to the support has remained controversial for decades. As a result, the development of catalytic support for such a purpose is only limited to typical reducible oxide materials. Herein, by using a combination of in situ spectroscopic and imaging technique, we are able to visualize and observe the atomic pathway for which hydrogen travels via a frustrated Lewis pair that has been constructed on a nonreducible metal oxide. The interchangeable status between the hydrogen, proton, and hydride is carefully characterized and demonstrated. It is envisaged that this study has opened up new design criteria for hydrogen storage material.

Published

2021

37. Induced Active Sites by Adsorbate in Zeotype Materials.

Author

Li G, Foo C, Yi X, Chen W, Zhao P, Gao P, Yoskamtorn T, Xiao Y, Day S, Tang CC, Hou G, Zheng A, and Tsang SCE

Abstract

There has been a long debate on how and where active sites are created for molecular adsorption and catalysis in zeolites, which underpin many important industrial applications. It is well accepted that Lewis acidic sites (LASs) and basic sites (LBSs) as active sites in pristine zeolites are generally believed to be the extra-framework Al species and residue anion (OH - ) species formed at fixed crystallographic positions after their synthesis. However, the dynamic interactions of adsorbates/reactants with pristine zeotype materials to "create" sites during real conditions remain largely unexplored. Herein, direct experimental observation of the establishment of induced active sites in silicoaluminophosphate (SAPO) by an adsorbate is for the first time made, which contradicts the traditional view of the fixed active sites in zeotype materials. Evidence shows that an induced frustrated Lewis pair (FLP, three-coordinated framework A l as LAS and Si O (H) as LBS) can be transiently favored for heterolytic molecular binding/reactions of competitive polar adsorbates due to their ineffective orbital overlap in the rigid framework. High-resolution magic-angle-spinning solid-state NMR, synchrotron X-ray diffraction, neutron powder diffraction, in situ diffuse reflectance infrared Fourier transform spectroscopy, and ab initio molecular dynamics demonstrate the transformation of a typical Brønsted acid site (Al(OH)Si) in SAPO zeolites to new induced FLP structure for hetereolytic binding upon adsorption of a strong polar adsorbate. Our unprecedented finding opens up a new avenue to understanding the dynamic establishment of active sites for adsorption or chemical reactions under molecular bombardment of zeolitic structures.

Published

2021

38. High Loading of Transition Metal Single Atoms on Chalcogenide Catalysts.

Author

Zheng J, Lebedev K, Wu S, Huang C, Ayvalı T, Wu TS, Li Y, Ho PL, Soo YL, Kirkland A, and Tsang SCE

Abstract

Transition metal doped chalcogenides are one of the most important classes of catalysts that have been attracting increasing attention for petrochemical and energy related chemical transformations due to their unique physiochemical properties. For practical applications, achieving maximum atom utilization by homogeneous dispersion of metals on the surface of chalcogenides is essential. Herein, we report a detailed study of a deposition method using thiourea coordinated transition metal complexes. This method allows the preparation of a library of a wide range of single atoms including both noble and non-noble transition metals (Fe, Co, Ni, Cu, Pt, Pd, Ru) with a metal loading as high as 10 wt % on various ultrathin 2D chalcogenides (MoS 2 , MoSe 2 , WS 2 and WSe 2 ). As demonstrated by the state-of-the-art characterization, the doped single transition metal atoms interact strongly with surface anions and anion vacancies in the exfoliated 2D materials, leading to high metal dispersion in the absence of agglomeration. Taking Fe on MoS 2 as a benchmark, it has been found that Fe is atomically dispersed until 10 wt %, and beyond this loading, formation of coplanar Fe clusters is evident. Atomic Fe, with a high electron density at its conduction band, exhibits a superior intrinsic activity and stability in CO 2 hydrogenation to CO per Fe compared to corresponding surface Fe clusters and other Fe catalysts reported for reverse water-gas-shift reactions.

Published

2021

39. Responses of Defect-Rich Zr-Based Metal-Organic Frameworks toward NH 3 Adsorption.

Author

Yoskamtorn T, Zhao P, Wu XP, Purchase K, Orlandi F, Manuel P, Taylor J, Li Y, Day S, Ye L, Tang CC, Zhao Y, and Tsang SCE

Abstract

Understanding structural responses of metal-organic frameworks (MOFs) to external stimuli such as the inclusion of guest molecules and temperature/pressure has gained increasing attention in many applications, for example, manipulation and manifesto smart materials for gas storage, energy storage, controlled drug delivery, tunable mechanical properties, and molecular sensing, to name but a few. Herein, neutron and synchrotron diffractions along with Rietveld refinement and density functional theory calculations have been used to elucidate the responsive adsorption behaviors of defect-rich Zr-based MOFs upon the progressive incorporation of ammonia (NH 3 ) and variable temperature. UiO-67 and UiO-bpydc containing biphenyl dicarboxylate and bipyridine dicarboxylate linkers, respectively, were selected, and the results establish the paramount influence of the functional linkers on their NH 3 affinity, which leads to stimulus-tailoring properties such as gate-controlled porosity by dynamic linker flipping, disorder, and structural rigidity. Despite their structural similarities, we show for the first time the dramatic alteration of NH 3 adsorption profiles when the phenyl groups are replaced by the bipyridine in the organic linker. These molecular controls stem from controlling the degree of H-bonding networks/distortions between the bipyridine scaffold and the adsorbed NH 3 without significant change in pore volume and unit cell parameters. Temperature-dependent neutron diffraction also reveals the NH 3 -induced rotational motions of the organic linkers. We also demonstrate that the degree of structural flexibility of the functional linkers can critically be affected by the type and quantity of the small guest molecules. This strikes a delicate control in material properties at the molecular level.

Published

2021

40. Characterisation of oxygen defects and nitrogen impurities in TiO 2 photocatalysts using variable-temperature X-ray powder diffraction.

Author

Foo C, Li Y, Lebedev K, Chen T, Day S, Tang C, and Tsang SCE

Abstract

TiO 2 -based powder materials have been widely studied as efficient photocatalysts for water splitting due to their low cost, photo-responsivity, earthly abundance, chemical and thermal stability, etc. In particular, the recent breakthrough of nitrogen-doped TiO 2 , which enhances the presence of structural defects and dopant impurities at elevated temperatures, exhibits an impressive visible-light absorption for photocatalytic activity. Although their electronic and optical properties have been extensively studied, the structure-activity relationship and photocatalytic mechanism remain ambiguous. Herein, we report an in-depth structural study of rutile, anatase and mixed phases (commercial P25) with and without nitrogen-doping by variable-temperature synchrotron X-ray powder diffraction. We report that an unusual anisotropic thermal expansion of the anatase phase can reveal the intimate relationship between sub-surface oxygen vacancies, nitrogen-doping level and photocatalytic activity. For highly doped anatase, a new cubic titanium oxynitride phase is also identified which provides important information on the fundamental shift in absorption wavelength, leading to excellent photocatalysis using visible light.

Published

2021

41. A rational study on the geometric and electronic properties of single-atom catalysts for enhanced catalytic performance.

Author

Xue Q, Xie Y, Wu S, Wu TS, Soo YL, Day S, Tang CC, Man HW, Yuen ST, Wong KY, Wang Y, Lo BTW, and Tsang SCE

Abstract

We investigate the geometric and electronic properties of single-atom catalysts (SACs) within metal-organic frameworks (MOFs) with respect to electrocatalytic CO2 reduction as a model reaction. A series of mid-to-late 3d transition metals have been immobilised within the microporous cavity of UiO-66-NH2. By employing Rietveld refinement of new-generation synchrotron diffraction, we not only identified the crystallographic and atomic parameters of the SACs that are stabilised with a robust MN(MOF) bonding of ca. 2.0 Å, but also elucidated the end-on coordination geometry with CO2. A volcano trend in the FEs of CO has been observed. In particular, the confinement effect within the rigid MOF can greatly facilitate redox hopping between the Cu SACs, rendering high FEs of CH4 and C2H4 at a current density of -100 mA cm-2. Although only demonstrated in selected SACs within UiO-66-NH2, this study sheds light on the rational engineering of molecular interactions(s) with SACs for the sustainable provision of fine chemicals.

Published

2020

42. Methanol Synthesis at a Wide Range of H 2 /CO 2 Ratios over a Rh-In Bimetallic Catalyst.

Author

Li MM, Zou H, Zheng J, Wu TS, Chan TS, Soo YL, Wu XP, Gong XQ, Chen T, Roy K, Held G, and Tsang SCE

Abstract

There is increasing interest in capturing H 2 generated from renewables with CO 2 to produce methanol. However, renewable hydrogen production is expensive and in limited quantity compared to CO 2 . Excess CO 2 and limited H 2 in the feedstock gas is not favorable for CO 2 hydrogenation to methanol, causing low activity and poor methanol selectivity. Now, a class of Rh-In catalysts with optimal adsorption properties to the intermediates of methanol production is presented. The Rh-In catalyst can effectively catalyze methanol synthesis but inhibit the reverse water-gas shift reaction under H 2 -deficient gas flow and shows the best competitive methanol productivity under industrially applicable conditions in comparison with reported values. This work demonstrates a strong potential of Rh-In bimetallic composition, from which a convenient methanol synthesis based on flexible feedstock compositions (such as H 2 /CO 2 from biomass derivatives) with lower energy cost can be established., (© 2020 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2020

43. 2D molybdenum disulphide nanosheets incorporated with single heteroatoms for the electrochemical hydrogen evolution reaction.

Author

Lau THM, Foord JS, and Tsang SCE

Abstract

2D nanosheets give enhanced surface area to volume ratios in particle morphology and they can also provide defined surface sites to disperse foreign atoms. Placing atoms of catalytic interest on 2D nanosheets as Single Atom Catalysts (SAC) represents one of the novel approaches due to their unique but tunable electronic and steric characteristics. Here in this mini-review, we particularly highlight some recent and important developments on heteroatom doped MoS 2 nanosheets (SAC-MoS 2 ) as catalysts for the electrochemical hydrogen evolution reaction (HER) from water, which could lead to opening up to a flagship of important renewable technologies in future. It is shown that the nature of dopants, doping positions and the polytypes of MoS 2 nanosheets are the determining factors in the overall catalytic abilities of these functionalised nanosheets. This may serve to obtain atomic models which lead to further understanding of the 'metal-support interaction' in catalysis.

Published

2020

44. Differential Adsorption of l- and d-Lysine on Achiral MFI Zeolites as Determined by Synchrotron X-Ray Powder Diffraction and Thermogravimetric Analysis.

Author

Chen T, Huang B, Day S, Tang CC, Tsang SCE, Wong KY, and Lo TWB

Abstract

Reported here is the first crystallographic observation of stereospecific bindings of l- and d-lysine (Lys) in achiral MFI zeolites. The MFI structure offers inherent geometric and internal confinement effects for the enantiomeric difference in l- and d-Lys adsorption. Notable differences have been observed by circular dichroism (CD) spectroscopy and thermogravimetric analysis (TGA). Distinct l- and d-Lys adsorption behaviours on the H-ZSM-5 framework have been revealed by the Rietveld refinement of high-resolution synchrotron X-ray powder diffraction (SXRD) data and the density-functional theory (DFT) calculations. Despite demonstrating the approach for l- and d-Lys over MFI zeolites at an atomistic resolution, the differential adsorption study sheds light on the rational engineering of molecular interaction(s) with achiral microporous materials for chiral separation purposes., (© 2020 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2020

45. Interstitial Boron Atoms in the Palladium Lattice of an Industrial Type of Nanocatalyst: Properties and Structural Modifications.

Author

Chen T, Ellis I, Hooper TJN, Liberti E, Ye L, Lo BTW, O'Leary C, Sheader AA, Martinez GT, Jones L, Ho PL, Zhao P, Cookson J, Bishop PT, Chater P, Hanna JV, Nellist P, and Tsang SCE

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 imply 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 11 B magic-angle-spinning (MAS) and 105 Pd 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- int B/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 105 Pd 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 enable the characterization of industrial metal nanocatalysts across length scales from macro- to microanalysis, which gives important guidance to the structure-activity relationship of the system.

Published

2019

46. Efficient Non-dissociative Activation of Dinitrogen to Ammonia over Lithium-Promoted Ruthenium Nanoparticles at Low Pressure.

Author

Zheng J, Liao F, Wu S, Jones G, Chen TY, Fellowes J, Sudmeier T, McPherson IJ, Wilkinson I, and Tsang SCE

Abstract

There is an exciting possibility to decentralize ammonia synthesis for fertilizer production or energy storage without carbon emission from H 2 obtained from renewables at small units operated at lower pressure. However, no suitable catalyst has yet been developed. Ru catalysts are known to be promoted by heavier alkali dopants. Instead of using heavy alkali metals, Li is herein shown to give the highest rate through surface polarisation despite its poorest electron donating ability. This exceptional promotion rate makes Ru-Li catalysts suitable for ammonia synthesis, which outclasses industrial Fe counterparts by at least 195 fold. Akin to enzyme catalysis, it is for the first time shown that Ru-Li catalysts hydrogenate end-on adsorbed N 2 stabilized by Li + on Ru terrace sites to ammonia in a stepwise manner, in contrast to typical N 2 dissociation on stepped sites adopted by Ru-Cs counterparts, giving new insights in activating N 2 by metallic catalysts., (© 2019 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2019

47. The Feasibility of Electrochemical Ammonia Synthesis in Molten LiCl-KCl Eutectics.

Author

McPherson IJ, Sudmeier T, Fellowes JP, Wilkinson I, Hughes T, and Tsang SCE

Abstract

Molten LiCl and related eutectic electrolytes are known to permit direct electrochemical reduction of N 2 to N 3- with high efficiency. It had been proposed that this could be coupled with H 2 oxidation in an electrolytic cell to produce NH 3 at ambient pressure. Here, this proposal is tested in a LiCl-KCl-Li 3 N cell and is found not to be the case, as the previous assumption of the direct electrochemical oxidation of N 3- to NH 3 is grossly over-simplified. We find that Li 3 N added to the molten electrolyte promotes the spontaneous and simultaneous chemical disproportionation of H 2 (H oxidation state 0) into H - (H oxidation state -1) and H + in the form of NH 2- /NH 2 - /NH 3 (H oxidation state +1) in the absence of applied current, resulting in non-Faradaic release of NH 3 . It is further observed that NH 2- and NH 2 - possess their own redox chemistry. However, these spontaneous reactions allow us to propose an alternative, truly catalytic cycle. By adding LiH, rather than Li 3 N, N 2 can be reduced to N 3- while stoichiometric amounts of H - are oxidised to H 2 . The H 2 can then react spontaneously with N 3- to form NH 3 , regenerating H - and closing the catalytic cycle. Initial tests show a peak NH 3 synthesis rate of 2.4×10 -8  mol cm -2  s -1 at a maximum current efficiency of 4.2 %. Isotopic labelling with 15 N 2 confirms the resulting NH 3 is from catalytic N 2 reduction., (© 2019 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2019

48. Photocatalytic water splitting by N-TiO 2 on MgO (111) with exceptional quantum efficiencies at elevated temperatures.

Author

Li Y, Peng YK, Hu L, Zheng J, Prabhakaran D, Wu S, Puchtler TJ, Li M, Wong KY, Taylor RA, and Tsang SCE

Abstract

Photocatalytic water splitting is attracting enormous interest for the storage of solar energy but no practical method has yet been identified. In the past decades, various systems have been developed but most of them suffer from low activities, a narrow range of absorption and poor quantum efficiencies (Q.E.) due to fast recombination of charge carriers. Here we report a dramatic suppression of electron-hole pair recombination on the surface of N-doped TiO 2 based nanocatalysts under enhanced concentrations of H + and OH - , and local electric field polarization of a MgO (111) support during photolysis of water at elevated temperatures. Thus, a broad optical absorption is seen, producing O 2 and H 2 in a 1:2 molar ratio with a H 2 evolution rate of over 11,000 μmol g -1  h -1 without any sacrificial reagents at 270 °C. An exceptional range of Q.E. from 81.8% at 437 nm to 3.2% at 1000 nm is also reported.

Published

2019

49. Unravelling the key role of surface features behind facet-dependent photocatalysis of anatase TiO 2 .

Author

Peng YK, Keeling B, Li Y, Zheng J, Chen T, Chou HL, Puchtler TJ, Taylor RA, and Tsang SCE

Abstract

The high activity of nanocrystallites is commonly attributed to the terminal high-energy facets. However, we demonstrate that the high activity of the anatase TiO2(001) facet in photocatalytic H2 evolution is not due to its high intrinsic surface energy, but local electronic effects created by surface features on the facet.

Published

2019

50. Structural dynamics of a metal-organic framework induced by CO 2 migration in its non-uniform porous structure.

Author

Zhao P, Fang H, Mukhopadhyay S, Li A, Rudić S, McPherson IJ, Tang CC, Fairen-Jimenez D, Tsang SCE, and Redfern SAT

Abstract

Stimuli-responsive behaviors of flexible metal-organic frameworks (MOFs) make these materials promising in a wide variety of applications such as gas separation, drug delivery, and molecular sensing. Considerable efforts have been made over the last decade to understand the structural changes of flexible MOFs in response to external stimuli. Uniform pore deformation has been used as the general description. However, recent advances in synthesizing MOFs with non-uniform porous structures, i.e. with multiple types of pores which vary in size, shape, and environment, challenge the adequacy of this description. Here, we demonstrate that the CO 2 -adsorption-stimulated structural change of a flexible MOF, ZIF-7, is induced by CO 2 migration in its non-uniform porous structure rather than by the proactive opening of one type of its guest-hosting pores. Structural dynamics induced by guest migration in non-uniform porous structures is rare among the enormous number of MOFs discovered and detailed characterization is very limited in the literature. The concept presented in this work provides new insights into MOF flexibility.

Published

2019