Your search keyword '"Collins, Sean M."' showing total 9 results

1. Mapping nanocrystalline disorder within an amorphous metal–organic framework.

Author

Sapnik, Adam F., Sun, Chao, Laulainen, Joonatan E. M., Johnstone, Duncan N., Brydson, Rik, Johnson, Timothy, Midgley, Paul A., Bennett, Thomas D., and Collins, Sean M.

Subjects

METAL-organic frameworks, DISTRIBUTION (Probability theory), UNIT cell, ELECTRON distribution, ORDER-disorder transitions, ELECTRON diffraction, METALLIC composites

Abstract

Intentionally disordered metal–organic frameworks (MOFs) display rich functional behaviour. However, the characterisation of their atomic structures remains incredibly challenging. X-ray pair distribution function techniques have been pivotal in determining their average local structure but are largely insensitive to spatial variations in the structure. Fe-BTC (BTC = 1,3,5-benzenetricarboxylate) is a nanocomposite MOF, known for its catalytic properties, comprising crystalline nanoparticles and an amorphous matrix. Here, we use scanning electron diffraction to first map the crystalline and amorphous components to evaluate domain size and then to carry out electron pair distribution function analysis to probe the spatially separated atomic structure of the amorphous matrix. Further Bragg scattering analysis reveals systematic orientational disorder within Fe-BTC's nanocrystallites, showing over 10° of continuous lattice rotation across single particles. Finally, we identify candidate unit cells for the crystalline component. These independent structural analyses quantify disorder in Fe-BTC at the critical length scale for engineering composite MOF materials. Framework materials containing amorphous and nanocrystalline phases are challenging to characterize as they are poorly represented by average structural descriptors, and thus microscopic to nanoscale analysis is often required. Here, scanning electron diffraction combined with electron pair distribution function analysis and Bragg scattering analysis are used to probe spatial variations in the structure of metal–organic framework Fe-BTC, known to comprise crystalline nanoparticles and an amorphous matrix. [ABSTRACT FROM AUTHOR]

Published

2023

2. Stepwise collapse of a giant pore metal–organic framework.

Author

Sapnik, Adam F., Johnstone, Duncan N., Collins, Sean M., Divitini, Giorgio, Bumstead, Alice M., Ashling, Christopher W., Chater, Philip A., Keeble, Dean S., Johnson, Timothy, Keen, David A., and Bennett, Thomas D.

Subjects

DISTRIBUTION (Probability theory), AMORPHIZATION, METAL-organic frameworks, BALL mills, POROSITY, POROUS metals

Abstract

Defect engineering is a powerful tool that can be used to tailor the properties of metal–organic frameworks (MOFs). Here, we incorporate defects through ball milling to systematically vary the porosity of the giant pore MOF, MIL-100 (Fe). We show that milling leads to the breaking of metal–linker bonds, generating additional coordinatively unsaturated metal sites, and ultimately causes amorphisation. Pair distribution function analysis shows the hierarchical local structure is partially retained, even in the amorphised material. We find that solvents can be used to stabilise the MIL-100 (Fe) framework against collapse, which leads to a substantial retention of porosity over the non-stabilised material. [ABSTRACT FROM AUTHOR]

Published

2021

3. Mixed hierarchical local structure in a disordered metal–organic framework.

Author

Sapnik, Adam F., Bechis, Irene, Collins, Sean M., Johnstone, Duncan N., Divitini, Giorgio, Smith, Andrew J., Chater, Philip A., Addicoat, Matthew A., Johnson, Timothy, Keen, David A., Jelfs, Kim E., and Bennett, Thomas D.

Subjects

METAL-organic frameworks, ELECTRON microscopy, ELECTRON pairs, ATOMIC structure, DISTRIBUTION (Probability theory)

Abstract

Amorphous metal–organic frameworks (MOFs) are an emerging class of materials. However, their structural characterisation represents a significant challenge. Fe-BTC, and the commercial equivalent Basolite® F300, are MOFs with incredibly diverse catalytic ability, yet their disordered structures remain poorly understood. Here, we use advanced electron microscopy to identify a nanocomposite structure of Fe-BTC where nanocrystalline domains are embedded within an amorphous matrix, whilst synchrotron total scattering measurements reveal the extent of local atomic order within Fe-BTC. We use a polymerisation-based algorithm to generate an atomistic structure for Fe-BTC, the first example of this methodology applied to the amorphous MOF field outside the well-studied zeolitic imidazolate framework family. This demonstrates the applicability of this computational approach towards the modelling of other amorphous MOF systems with potential generality towards all MOF chemistries and connectivities. We find that the structures of Fe-BTC and Basolite® F300 can be represented by models containing a mixture of short- and medium-range order with a greater proportion of medium-range order in Basolite® F300 than in Fe-BTC. We conclude by discussing how our approach may allow for high-throughput computational discovery of functional, amorphous MOFs. The structures of amorphous MOFs are challenging to characterise. Here the authors use electron microscopy and pair distribution function methods, coupled with a polymerisation-based algorithm to determine the atomic structure of Fe-BTC, demonstrating the power of this computational approach. [ABSTRACT FROM AUTHOR]

Published

2021

4. Phase diagrams of liquid-phase mixing in multi-component metal-organic framework glasses constructed by quantitative elemental nano-tomography.

Author

Collins, Sean M., MacArthur, Katherine E., Longley, Louis, Tovey, Robert, Benning, Martin, Schönlieb, Carola-Bibiane, Bennett, Thomas D., and Midgley, Paul A.

Subjects

PHASE diagrams, METAL-organic frameworks, ENERGY dispersive X-ray spectroscopy, GLASS, MOLTEN glass, SCANNING electron microscopes, LIQUID phase epitaxy, TRANSMISSION electron microscopes

Abstract

Several distinct mixing processes and resulting microstructures have recently been reported in multicomponent glasses prepared from multiple metal-organic frameworks. Here, two illustrative examples of multicomponent zeolitic imidazolate framework (ZIF) glasses, the (aTZIF-4-Co)0.5(agZIF-62)0.5 blend and the ag[(ZIF-67)0.2(ZIF-62)0.8] flux melted glass, are studied. These materials are characterized by quantitative X-ray energy dispersive spectroscopy in the scanning transmission electron microscope. By advancing a partial ionization cross section methodology using standards of arbitrary morphology, quantitative nanoscale elemental analysis throughout the glass volume is achieved. In turn, phase diagrams describing the mixing states are presented, offering mechanistic insight into the formation of the observed microstructures. Significant miscibility was observed in ag[(ZIF-67)0.2(ZIF-62)0.8]. These findings establish phase-segregation and interdiffusion as two processes in multicomponent glass formation, which explains the different outcomes observed in blending and flux melting. [ABSTRACT FROM AUTHOR]

Published

2019

5. Liquid phase blending of metal-organic frameworks.

Author

Longley, Louis, Collins, Sean M., Chao Zhou, Smales, Glen J., Norman, Sarah E., Brownbill, Nick J., Ashling, Christopher W., Chater, Philip A., Tovey, Robert, Schönlieb, Carola-Bibiane, Headen, Thomas F., Terrill, Nicholas J., Yuanzheng Yue, Smith, Andrew J., Blanc, Frédéric, Keen, David A., Midgley, Paul A., and Bennett, Thomas D.

Subjects

METAL-organic frameworks, NUCLEAR magnetic resonance spectroscopy, NANOINDENTATION, ION transport (Biology), GLASS transitions, LIQUID phase epitaxy

Abstract

The liquid and glass states of metal–organic frameworks (MOFs) have recently become of interest due to the potential for liquid-phase separations and ion transport, alongside the fundamental nature of the latter as a new, fourth category of melt-quenched glass. Here we show that the MOF liquid state can be blended with another MOF component, resulting in a domain structured MOF glass with a single, tailorable glass transition. Intra-domain connectivity and short range order is confirmed by nuclear magnetic resonance spectroscopy and pair distribution function measurements. The interfacial binding between MOF domains in the glass state is evidenced by electron tomography, and the relationship between domain size and Tg investigated. Nanoindentation experiments are also performed to place this new class of MOF materials into context with organic blends and inorganic alloys. [ABSTRACT FROM AUTHOR]

Published

2018

6. Extraction of 3D quantitative maps using EDS-STEM tomography and HAADF-EDS bimodal tomography.

Author

Yuan, Yu, MacArthur, Katherine E., Collins, Sean M., Brodusch, Nicolas, Voisard, Frédéric, Dunin-Borkowski, Rafal E., and Gauvin, Raynald

Subjects

*MONTE Carlo method, *METAL-organic frameworks, *X-rays, *TOMOGRAPHY

Abstract

• A novel quantification approach is proposed for STEM tomography. • 3D high-resolution quantitative element maps are reconstructed. • HAADF-EDS bimodal tomography shows advantages compared with EDS-STEM tomography. Electron tomography has been widely applied to three-dimensional (3D) morphology characterization and chemical analysis at the nanoscale. A HAADF-EDS bimodal tomographic (HEBT) reconstruction technique has been developed to extract high resolution element-specific information. However, the reconstructed elemental maps cannot be directly converted to quantitative compositional information. In this work, we propose a quantification approach for obtaining elemental weight fraction maps from the HEBT reconstruction technique using the physical parameters extracted from a Monte Carlo code, MC X-ray. A similar quantification approach is proposed for the EDS-STEM tomographic reconstruction. The performance of the two quantitative reconstruction methods, using the simultaneous iterative reconstruction technique, are evaluated and compared for a simulated dataset of a two-dimensional phantom sample. The effects of the reconstruction parameters including the number of iterations and the weight of the HAADF signal are discussed. Finally, the two approaches are applied to an experimental dataset to show the 3D structure and quantitative elemental maps of a particle of flux melted metal-organic framework glass. [ABSTRACT FROM AUTHOR]

Published

2021

7. Droplet-based millifluidic synthesis of a proton-conducting sulfonate metal–organic framework.

Author

Sun, Chao, Barton, Matthew, Pask, Christopher M., Edokali, Mohamed, Yang, Lina, Britton, Andrew J., Micklethwaite, Stuart, Iacoviello, Francesco, Hassanpour, Ali, Besenhard, Maximilian, Drummond-Brydson, Rik, Wu, Ke-Jun, and Collins, Sean M.

Subjects

*METAL-organic frameworks, *POLYVINYLIDENE fluoride, *PROTON conductivity, *PARTICLE size distribution, *CHEMICAL yield, *FACTORIAL experiment designs, *PROTONS

Abstract

[Display omitted] • Continuous millifluidic synthesis of the sulfonate metal–organic framework Cu-SAT. • Reactor parameters determine reaction yield and Cu-SAT particle size. • Design of experiments revealed trade-offs in yield and particle size control. • Cu-SAT based mixed-matrix membranes showed a promising proton conductivity. Metal–organic frameworks (MOFs) have emerged as promising candidate materials for proton exchange membranes (PEMs), due to the control of proton transport enabled by functional groups and the structural order within the MOFs. In this work, we report a millifluidic approach for the synthesis of a MOF incorporating both sulfonate and amine groups, termed Cu-SAT, which exhibits a high proton conductivity. The fouling-free multiphase flow reactor synthesis was operated for more than 5 h with no reduction in yield or change in the particle size distribution, demonstrating a sustained space–time yield up to 131.7 kg m−3 day−1 with consistent particle quality. Reaction yield and particle size were controllably tuned by the adjustment of reaction parameters, such as residence/reaction time, temperature, and reagent concentration. The reaction yields from the flow reactor were 10–20% higher than those of corresponding batch syntheses, indicating improved mass and heat transfer in flow. A systematic exploration of synthetic parameters using a factorial design of experiments approach revealed the key correlations between the process parameters and yields and particle size distributions. The proton conductivity of the synthesized Cu-SAT MOF was evaluated in a mixed matrix membrane model PEM with polyvinylpyrrolidone and polyvinylidene fluoride polymers, exhibiting a promising composite conductivity of 1.34 ± 0.05 mS cm−1 at 353 K and 95% relative humidity (RH). [ABSTRACT FROM AUTHOR]

Published

2023

8. Metal-organic framework crystal-glass composites

Author

Andraž Krajnc, David A. Keen, Marie-Vanessa Coulet, Jingwei Hou, Vicki Chen, Sean M. Collins, Philip A. Chater, Louis Longley, Gregor Mali, Chao Zhou, Duncan N. Johnstone, Christopher W. Ashling, Paul A. Midgley, Thomas D. Bennett, François-Xavier Coudert, Philip L. Llewellyn, Shichun Li, Department of Materials Science and Metallurgy [Cambridge University] (DMSM), University of Cambridge [UK] (CAM), National Institute of Chemistry, Matériaux divisés, interfaces, réactivité, électrochimie (MADIREL), Aix Marseille Université (AMU)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS), Institut de Recherche de Chimie Paris (IRCP), Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS)-Ecole Nationale Supérieure de Chimie de Paris - Chimie ParisTech-PSL (ENSCP), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Ministère de la Culture (MC), STFC Rutherford Appleton Laboratory (RAL), Science and Technology Facilities Council (STFC), University of New South Wales [Sydney] (UNSW), University of Queensland [Brisbane], Ecole Nationale Supérieure de Chimie de Paris - Chimie ParisTech-PSL (ENSCP), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS)-Ministère de la Culture (MC), Ashling, Christopher W [0000-0002-9528-6595], Collins, Sean M [0000-0002-5151-6360], Zhou, Chao [0000-0003-0218-3114], Longley, Louis [0000-0002-9178-9603], Johnstone, Duncan N [0000-0003-3663-3793], Chater, Philip A [0000-0002-5513-9400], Coudert, François-Xavier [0000-0001-5318-3910], Keen, David A [0000-0003-0376-2767], Mali, Gregor [0000-0002-9012-2495], Bennett, Thomas D [0000-0003-3717-3119], and Apollo - University of Cambridge Repository

Subjects

0301 basic medicine, Materials science, Chemical structure, Science, Composite number, General Physics and Astronomy, 02 engineering and technology, Article, General Biochemistry, Genetics and Molecular Biology, Matrix (geology), 03 medical and health sciences, Phase (matter), Porous materials, Organic-inorganic nanostructures, Composite material, lcsh:Science, 0912 Materials Engineering, Multidisciplinary, Glasses, 0303 Macromolecular and Materials Chemistry, [CHIM.MATE]Chemical Sciences/Material chemistry, General Chemistry, Metal-organic frameworks, 021001 nanoscience & nanotechnology, Co2 adsorption, 030104 developmental biology, Lead glass, visual_art, visual_art.visual_art_medium, lcsh:Q, Metal-organic framework, 0210 nano-technology, Porous medium

Abstract

The majority of research into metal-organic frameworks (MOFs) focuses on their crystalline nature. Recent research has revealed solid-liquid transitions within the family, which we use here to create a class of functional, stable and porous composite materials. Described herein is the design, synthesis, and characterisation of MOF crystal-glass composites, formed by dispersing crystalline MOFs within a MOF-glass matrix. The coordinative bonding and chemical structure of a MIL-53 crystalline phase are preserved within the ZIF-62 glass matrix. Whilst separated phases, the interfacial interactions between the closely contacted microdomains improve the mechanical properties of the composite glass. More significantly, the high temperature open pore phase of MIL-53, which spontaneously transforms to a narrow pore upon cooling in the presence of water, is stabilised at room temperature in the crystal-glass composite. This leads to a significant improvement of CO2 adsorption capacity., The formation of composite materials has been widely exploited to alter the chemical and physical properties of their components. Here the authors form metal–organic framework (MOF) crystal–glass composites in which a MOF glass matrix stabilises the open pore structure of MIL-53, leading to enhanced CO2 adsorption.

Published

2019

9. Mixed hierarchical local structure in a disordered metal–organic framework

Author

Sean M. Collins, Giorgio Divitini, Duncan N. Johnstone, Philip A. Chater, Adam F. Sapnik, Timothy Johnson, Thomas D. Bennett, David A. Keen, Irene Bechis, Matthew Addicoat, Kim E. Jelfs, Andrew J. Smith, Sapnik, Adam F. [0000-0001-6200-4208], Collins, Sean M. [0000-0002-5151-6360], Johnstone, Duncan N. [0000-0003-3663-3793], Divitini, Giorgio [0000-0003-2775-610X], Smith, Andrew J. [0000-0003-3745-7082], Chater, Philip A. [0000-0002-5513-9400], Addicoat, Matthew A. [0000-0002-5406-7927], Johnson, Timothy [0000-0003-4651-7374], Keen, David A. [0000-0003-0376-2767], Jelfs, Kim E. [0000-0001-7683-7630], Bennett, Thomas D. [0000-0003-3717-3119], and Apollo - University of Cambridge Repository

Subjects

Materials science, Atomic order, 123, Science, General Physics and Astronomy, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Local structure, General Biochemistry, Genetics and Molecular Biology, Amorphous matrix, 128, Multidisciplinary, Nanocomposite, 639/301/1034/1035, article, Pair distribution function, General Chemistry, Metal-organic frameworks, 021001 nanoscience & nanotechnology, Nanocrystalline material, 0104 chemical sciences, Amorphous solid, Atomistic models, 639/638/298/921, Metal-organic framework, 0210 nano-technology, Zeolitic imidazolate framework

Abstract

Amorphous metal–organic frameworks (MOFs) are an emerging class of materials. However, their structural characterisation represents a significant challenge. Fe-BTC, and the commercial equivalent Basolite® F300, are MOFs with incredibly diverse catalytic ability, yet their disordered structures remain poorly understood. Here, we use advanced electron microscopy to identify a nanocomposite structure of Fe-BTC where nanocrystalline domains are embedded within an amorphous matrix, whilst synchrotron total scattering measurements reveal the extent of local atomic order within Fe-BTC. We use a polymerisation-based algorithm to generate an atomistic structure for Fe-BTC, the first example of this methodology applied to the amorphous MOF field outside the well-studied zeolitic imidazolate framework family. This demonstrates the applicability of this computational approach towards the modelling of other amorphous MOF systems with potential generality towards all MOF chemistries and connectivities. We find that the structures of Fe-BTC and Basolite® F300 can be represented by models containing a mixture of short- and medium-range order with a greater proportion of medium-range order in Basolite® F300 than in Fe-BTC. We conclude by discussing how our approach may allow for high-throughput computational discovery of functional, amorphous MOFs., The structures of amorphous MOFs are challenging to characterise. Here the authors use electron microscopy and pair distribution function methods, coupled with a polymerisation-based algorithm to determine the atomic structure of Fe-BTC, demonstrating the power of this computational approach.

Published

2021