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3. Label-free TOF-SIMS imaging of sulfur producing enzymes inside microglia cells following exposure to silver nanowires

Author

Leo, BF, Fearn, S, Gonzalez-Carter, D, Theodorou, I, Ruenraroengsak, P, Goode, A, Mcphail, D, Dexter, DT, Shaffer, MSP, Chung, KF, Porter, AE, and Ryan, MP

Subjects
Chemistry, Science & Technology, TOF-SIMS, TISSUE, Physical Sciences, Chemistry, Analytical, 0399 Other Chemical Sciences, 0904 Chemical Engineering, 0301 Analytical Chemistry, Analytical Chemistry
Abstract

There are no methods sensitive enough to detect enzymes within cells, without the use of analyte labelling. Here we show that it is possible to detect protein ion signals of three different H2S-synthesizing enzymes inside microglia after pre-treatment with silver nanowires (AgNW) using time of flight-secondary ion mass spectrometry (TOF-SIMS). Protein fragment ions, including the fragment of amino acid (C4H8N+ - 70 amu), fragments of the sulfur producing cystathionine-containing enzymes and the Ag+ ion signal could be detected without the use of any labels; the cells were mapped using the C4H8N+ amino acid fragment. Scanning electron microscopy imaging and energy dispersive x-ray chemical analysis showed that the AgNWs were inside the same cells imaged by TOF-SIMS and transformed chemically into crystalline Ag2S within cells in which the sulfur producing proteins were detected. The presence of these sulfur producing cystathionine-containing enzymes within the cells was confirmed by Western Blots and confocal microscopy images of fluorescently labelled antibodies against the sulfur producing enzymes. Label-free ToF-SIMS is very promising for the label-free identification of H2S-contributing enzymes and their cellular localization in biological systems. The technique could in future be used to identify which of these enzymes are most contributory.

Published
2019

4. Local structure and polar order in liquid N-Methyl-2-pyrrolidone (NMP)

Author

Basma, NS, Headen, TF, Shaffer, MSP, Skipper, NT, and Howard, CA

Subjects
GRAPHENE, WALLED CARBON NANOTUBES, Science & Technology, SPONTANEOUS DISSOLUTION, SOLUBILITY PARAMETERS, 02 Physical Sciences, Chemistry, Physical, PHASE EXFOLIATION, 09 Engineering, N-METHYLPYRROLIDONE, FULLERIDE ANIONS, Chemistry, NEUTRON-SCATTERING, Physical Sciences, PI-PI INTERACTIONS, 03 Chemical Sciences, LAYERED MATERIALS
Abstract

N-Methyl-2-pyrrolidone (NMP) is an exceptional solvent, widely used in industry and for nanomaterials processing. Yet despite its ubiquity, its liquid structure, which ultimately dictates its solvation properties, is not fully known. Here, neutron scattering is used to determine NMP’s structure in unprecedented detail. Two dominant nearest-neighbor arrangements are found, where rings are parallel or perpendicular. However, compared with related solvents, NMP has a relatively large population of parallel approaches, similar only to benzene, despite its nonaromaticity and the presence of the normally structure-reducing methyl group. This arrangement is underpinned by NMP’s dipole moment, which has a profound effect on its structure: nearest-neighbor molecules arrange in an antiparallel but offset fashion. This polar-induced order extends beyond the first solvation shell, resulting in ordered trimers that reach the nanometer range. The degree of order and balance of interactions rationalize NMP’s high boiling point and versatile capabilities to solvate both charged and uncharged species.

Published
2018

5. MBE growth and morphology control of ZnO nanobelts with polar axis perpendicular to growth direction

Author

Kennedy, OW, Coke, ML, White, ER, Shaffer, MSP, Warburton, PA, and Engineering & Physical Science Research Council (EPSRC)

Subjects
Nanobelts, Technology, Science & Technology, MBE, Nanowires, Physics, Materials Science, Physics::Optics, Materials Science, Multidisciplinary, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, 09 Engineering, Physics, Applied, Condensed Matter::Materials Science, Physical Sciences, Zinc oxide, 03 Chemical Sciences, Materials
Abstract

In quasi-one-dimensional polar nanostructures the relative orientation of the long and polar axes will determine how the polarity of the nanostructure may be exploited for applications. Here we present the growth by molecular-beam epitaxy of quasi-1d ZnO nanostructures (specifically nanobelts) with the polar axis perpendicular to the growth axis. We demonstrate the control of nanostructure morphology by growth temperature. Our work represents a key milestone towards the development of future polarization-engineered oxide heterostructures embedded in quasi-1d nanodevices.

Published
2017

6. Hybrid effects in graphene oxide/carbon nanotube-supported Layered Double Hydroxides: Enhancing the CO₂ sorption properties

Author

De Marco, M, Menzel, R, Bawaked, SM, Mokhtar, M, Obaid, AY, Basahel, SN, and Shaffer, MSP

Abstract

Graphene oxide (GO) and multi-walled carbon nanotubes (MWCNT) have been previously used independently as active supports for Layered Double Hydroxides (LDH), and found to enhance the intrinsic CO₂ sorption capacity of the adsorbents. However, the long-term stability of the materials subjected to temperature-swing adsorption (TSA) cycles still requires improvement. In this contribution, GO and MWCNT are hybridized to produce mixed substrates with improved surface area and compatibility for the deposition of LDH platelets, compared to either phase alone. The incorporation of a robust and thoroughly hybridized carbon network considerably enhances the thermal stability of activated, promoted LDH over twenty cycles of gas adsorption-desorption (96% of retention of the initial sorption capacity at the 20th cycle), dramatically reducing the sintering previously observed when either GO or MWCNT were added separately. Detailed characterization of the morphology of the supported LDH, at several stages of the multicycle adsorption process, shows that the initial morphology of the adsorbents is more strongly retained when supported on the robust hybrid GO/MWCNT network; the CO₂ adsorption performance correlates closely with the specific surface area of the adsorbents, with both maximized at small loadings of a 1:1 ratio of GO:MWCNT substrate.

Published
2017

7. Crack arrest in finger jointed thermoplastic interleaved CFRC

Author

Anthony, DB, Bacarreza Nogales, OR, Shaffer, MSP, Bismarck, A, Robinson, P, Pimenta, S, and Engineering & Physical Science Research Council (E

Subjects
body regions, human activities
Abstract

Pre-cut unidirectional carbon fibre prepreg (M21/194/34%/T800S) composites were tested in tension with a 20 mm overlapped finger joint architectures. In between the overlapping finger jointed region the effect of introducing polyethersulfone (PES) interleaves is investigated. Samples with the addition of a thick PES interleave arrested the initial crack which formed at the pre-cut site. The strain-to-failure of the thick PES interleaved samples was over 3.2%, an increase of 85% compared to the baseline samples, and catastrophic failure was delayed in the majority of instances.

Published
2017

8. Colloidal Cu/ZnO catalysts for the hydrogenation of carbon dioxide to methanol: investigating catalyst preparation and ligand effects

Author

Pike, SD, García-Trenco, A, White, ER, Leung, A, Weiner, J, Shaffer, MSP, Williams, CK, and Engineering & Physical Science Research Council (EPSRC)

Subjects
CO2 HYDROGENATION, Science & Technology, Chemistry, Physical, LIQUID-PHASE METHANOL, NANOCRYSTAL SURFACES, PALLADIUM NANOPARTICLES, PARTICLE-SIZE, METAL-SUPPORT INTERACTIONS, Chemistry, GAS, Physical Sciences, ZNO, ACTIVE-SITES, CU
Abstract

The production of methanol from CO 2 hydrogenation is a promising potential route to a renewable liquid fuel and renewable energy vector. Herein, three distinct routes to make colloidal catalysts based on mixtures of Cu(0) and ZnO nanoparticles (NPs) and using low-temperature organometallic procedures are reported. The colloids are surface coordinated by a phosphinate ligand: dioctylphosphinate ([DOPA] - ), which delivers a high solubility in organic solvents. Further, the synthetic routes allow fine control of the ZnO:Cu and ligand loadings. The catalysts are prepared by mixing s mall NPs (2 nm) of either Cu(0) or air-stable Cu 2 O NPs with ZnO NPs (3 nm), or by the synthesis of Cu(0) in presence of ZnO NPs (ZnO: 2 nm, Cu: 6 nm). The resulting colloidal catalysts are applied in the liquid phase hydrogenation of CO 2 to methanol (210 °C, 50 bar, 3:1 molar ratio of CO 2 :H 2 ). The catalysts typically exhibit 3 times higher rates when compared to a heterogeneous Cu-ZnO-Al 2 O 3 commercial catalyst (21 vs. 7 mmol MeOH g CuZnO -1 h -1 ). The characterisation of the post-catalysis colloids show clear Cu/ZnO interfaces (HR-TEM), which are formed under reducing conditions, as well as differences in the Cu(0) NP size (from 3 to 7 nm) and nanoscale restructuring of the catalysts. The combination of characterisation and catalytic results indicate that the activity is mostly dictated by the Cu(0) particle size and ligand loading. Smaller Cu(0) NPs exhibited lower turnover frequency (TOF) values, whereas higher ligand loadings ([DOPA] - :(Cu + Zn) of 0.2-1.1) lead to smaller Cu(0) NPs and reduce the formation of Cu/ZnO interfaces. UV-vis spectroscopy reveals that the Cu(0) NPs are more stable to oxidation under air after catalysis than beforehand, potentially due to migration of ZnO onto the Cu surface whilst under catalytic conditions.

Published
2017

9. Applying a potential difference to minimise damage to carbon fibres during carbon nanotube grafting by chemical vapour deposition

Author

Anthony, DB, Qian, H, Clancy, AJ, Bismarck, A, Greenhalgh, ES, Shaffer, MSP, and Engineering & Physical Science Research Council (E

Subjects
Technology, Science & Technology, synthesis, Physics, carbon fibre, IN-SITU, Materials Science, FIELD-DIRECTED GROWTH, Materials Science, Multidisciplinary, MECHANICAL-PROPERTIES, Physics, Applied, chemical vapour deposition, potential difference enhanced, HIGH-PERFORMANCE, Physical Sciences, MD Multidisciplinary, Science & Technology - Other Topics, HIERARCHICAL COMPOSITES, Nanoscience & Nanotechnology, carbon nanotube, HYBRID, CATALYTIC GROWTH, MULTISCALE-REINFORCEMENT, EPOXY COMPOSITE, NANOFIBERS
Abstract

The application of an in-situ potential difference between carbon fibres and a graphite foil counter electrode (300 V, generating an electric field ca. 0.3 V μm-1 to 0.7 V μm-1) during the chemical vapour deposition synthesis of carbon nanotube (CNT) grafted carbon fibres, significantly improves the uniformity of growth without reducing the tensile properties of the underlying carbon fibres. Grafted carbon nanotubes with diameters around 55 nm and lengths around 10 μm were well attached to the carbon fibre surface, and were grown without the requirement for protective barrier coatings. The grafted CNTs increased the surface area to 185 m2 g-1 compared to the as-received sized carbon fibre 0.24 m2 g-1. The approach is not restricted to batch systems and has the potential to improve carbon nanotube grafted carbon fibre production for continuous processing.

Published
2017

11. Mononuclear Phenolate Diamine Zinc Hydride Complexes and Their Reactions With CO2

Author

Brown, NJ, Harris, JE, Yin, X, Silverwood, I, White, AJP, Kazarian, SG, Hellgardt, K, Shaffer, MSP, and Williams, CK

Subjects
Article
Abstract

The synthesis, characterization, and zinc coordination chemistry of the three proligands 2-tert-butyl-4-[tert-butyl (1)/methoxy (2)/nitro (3)]-6-{[(2′-dimethylaminoethyl)methylamino]methyl}phenol are described. Each of the ligands was reacted with diethylzinc to yield zinc ethyl complexes 4–6; these complexes were subsequently reacted with phenylsilanol to yield zinc siloxide complexes 7–9. Finally, the zinc siloxide complexes were reacted with phenylsilane to produce the three new zinc hydride complexes 10–12. The new complexes 4–12 have been fully characterized by NMR spectroscopy, mass spectrometry, and elemental analyses. The structures of the zinc hydride complexes have been probed using VT-NMR spectroscopy and X-ray diffraction experiments. These data indicate that the complexes exhibit mononuclear structures at 298 K, both in the solid state and in solution (d8-toluene). At 203 K, the NMR signals broaden, consistent with an equilibrium between the mononuclear and dinuclear bis(μ-hydrido) complexes. All three zinc hydride complexes react rapidly and quantitatively with carbon dioxide, at 298 K and 1 bar of pressure over 20 min, to form the new zinc formate complexes 13–15. The zinc formate complexes have been analyzed by NMR spectroscopy and VT-NMR studies, which reveal a temperature-dependent monomer–dimer equilibrium that is dominated by the mononuclear species at 298 K.

Published
2014

12. Chemical routes to discharging graphenides

Author

Hodge, SA, Buckley, D, Yau, HC, Skipper, N, Howard, C, Shaffer, MSP, and Engineering & Physical Science Research Council (EPSRC)

Subjects
Technology, WALLED CARBON NANOTUBES, Science & Technology, 02 Physical Sciences, AROMATIC-HYDROCARBONS, Chemistry, Multidisciplinary, Physics, Materials Science, ELECTROCHEMICAL PROPERTIES, Materials Science, Multidisciplinary, LIQUID-AMMONIA, APROTIC MEDIA, Physics, Applied, FULLERIDE ANIONS, Chemistry, RAMAN-SPECTROSCOPY, 10 Technology, Physical Sciences, Science & Technology - Other Topics, INTERCALATION COMPOUNDS, Nanoscience & Nanotechnology, 03 Chemical Sciences, X-RAY PHOTOELECTRON, INCREASED SOLUBILITY
Abstract

Chemical and electrochemical reduction methods allow the dispersion, processing, and/or functionalization of discrete sp 2 - hybridised nanocarbons, including fullerenes, nanotubes and graphenes. Electron transfer to the nanocarbon raises the Fermi energy creating nanocar bon anions, thereby activating an array of possible covalent reactions. The Fermi level may then be partially or fully lowered by intended functionalization reactions, but in general, techniques are required to remove excess charge without inadvertent cova lent reactions that potentially degrade the nanocarbon properties of interest. Here, simple and effective chemical discharging routes are demonstrated for graphenide polyelectrolytes and are expected to apply to other systems, particularly nanotubides. The discharging process is inherently linked to the reduction potentials of such chemical discharging agents and the unusual fundamental chemistry of charged nanocarbons.

Published
2017

13. Avoiding artefacts during electron microscopy of silver nanomaterials exposed to biological environments

Author

Chen, S, Goode, AE, Skepper, JN, Thorley, AJ, Seiffert, JM, Chung, KF, Tetley, TD, Shaffer, MSP, Ryan, MP, and Porter, AE

Subjects
Microscopy, electron microscopy, biological sample preparation, 0204 Condensed Matter Physics, silver nanomaterials, toxicity, 0601 Biochemistry And Cell Biology, staining, Artefacts, 0912 Materials Engineering, resin embedding, sulfidation
Published
2014

17. Mechanical, electrical and microstructural characterisation of multifunctional structural power composites

Author

Greenhalgh, ES, primary, Ankersen, J, additional, Asp, LE, additional, Bismarck, A, additional, Fontana, QPV, additional, Houlle, M, additional, Kalinka, G, additional, Kucernak, A, additional, Mistry, M, additional, Nguyen, S, additional, Qian, H, additional, Shaffer, MSP, additional, Shirshova, N, additional, Steinke, JHG, additional, and Wienrich, M, additional

Published
2014
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19. Mechanical, electrical and microstructural characterisation of multifunctional structural power composites.

Author

Greenhalgh, ES, Ankersen, J, Asp, LE, Bismarck, A, Fontana, QPV, Houlle, M, Kalinka, G, Kucernak, A, Mistry, M, Nguyen, S, Qian, H, Shaffer, MSP, Shirshova, N, Steinke, JHG, and Wienrich, M

Subjects
SUPERCAPACITORS, MICROSTRUCTURE, MECHANICAL loads, ELECTRIC conductivity, IONIC liquids, CARBON nanotubes
Abstract

Multifunctional composites which can fulfil more than one role within a system have attracted considerable interest. This work focusses on structural supercapacitors which simultaneously carry mechanical load whilst storing/delivering electrical energy. Critical mechanical properties (in-plane shear and in-plane compression performance) of two monofunctional and four multifunctional materials were characterised, which gave an insight into the relationships between these properties, the microstructures and fracture processes. The reinforcements included baseline T300 fabric, which was then either grafted or sized with carbon nanotubes, whilst the baseline matrix was MTM57, which was blended with ionic liquid and lithium salt (two concentrations) to imbue multifunctionality. The resulting composites exhibited a high degree of matrix heterogeneity, with the ionic liquid phase preferentially forming at the fibres, resulting in poor matrix-dominated properties. However, fibre-dominated properties were not depressed. Thus, it was demonstrated that these materials can now offer weight savings over conventional monofunctional systems when under modest loading. [ABSTRACT FROM AUTHOR]

Published
2015
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20. Multifunctional structural supercapacitors for electrical energy storage applications.

Author

Javaid, A, Ho, KKC, Bismarck, A, Shaffer, MSP, Steinke, JHG, and Greenhalgh, ES

Subjects
SUPERCAPACITORS, ELECTRICAL energy, ENERGY storage, ELECTRIC insulators & insulation, POLYELECTROLYTES, ELECTRIC capacity
Abstract

A novel concept of structural supercapacitors based on carbon fibre-reinforced composites has been introduced that can simultaneously act as a structural component and an electrical energy storing device. Supercapacitors consisting of woven carbon fibre mat electrodes; filter paper insulator and crosslinked poly(ethylene glycol) diglycidylether/diglycidylether of bisphenol-A polymer electrolytes were fabricated. Brunauer–Emmett–Teller surface area analysis and tensile tests were conducted on the as-received and activated carbon fibre reinforcements. Compression tests and ionic conductivity measurements were conducted on the polymer electrolytes while charge/discharge electrochemical tests and shear testing were done on the structural supercapacitors. This was to investigate the implications of increased diglycidylether of bisphenol-A loading in crosslinked poly(ethylene glycol) diglycidylether polymer electrolytes and carbon fibre activation on the multifunctionality of structural supercapacitors. The addition of diglycidylether of bisphenol-A increased the compressive stiffness, although the ionic conductivity was compromised. Specific capacitance of the structural supercapacitors was increased with the chemical activation of carbon fibre electrodes. Carbon fibre activation led to improved specific capacitance of the structural supercapacitors and the addition of diglycidylether of bisphenol-A increased the shear modulus, although the specific capacitance was compromised. [ABSTRACT FROM PUBLISHER]

Published
2014
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21. Single Crystal, Luminescent Carbon Nitride Nanosheets Formed by Spontaneous Dissolution

Author

Miller, TS, Suter, TM, Telford, AM, Picco, L, Payton, OD, Russell-Pavier, F, Cullen, PL, Sella, A, Shaffer, MSP, Nelson, J, Tileli, V, McMillan, PF, Howard, CA, and Commission of the European Communities

Subjects
GRAPHENE, Technology, two-dimensional material, SOLAR-CELLS, Chemistry, Multidisciplinary, Materials Science, PHOTOCATALYST, Materials Science, Multidisciplinary, QUANTUM DOTS, FUEL-CELLS, Physics, Applied, POLY(TRIAZINE IMIDE), Nanoscience & Nanotechnology, solution, photoactive, EXFOLIATION, Science & Technology, HYDROGEN EVOLUTION, Chemistry, Physical, Physics, Nanomaterial, Chemistry, Physics, Condensed Matter, LAYER, Physical Sciences, Science & Technology - Other Topics, VISIBLE-LIGHT
Abstract

A primary method for the production of 2D nanosheets is liquid-phase delamination from their 3D layered bulk analogues. Most strategies currently achieve this objective by significant mechanical energy input or chemical modification but these processes are detrimental to the structure and properties of the resulting 2D nanomaterials. Bulk poly(triazine imide) (PTI)-based carbon nitrides are layered materials with a high degree of crystalline order. Here, we demonstrate that these semiconductors are spontaneously soluble in select polar aprotic solvents, that is, without any chemical or physical intervention. In contrast to more aggressive exfoliation strategies, this thermodynamically driven dissolution process perfectly maintains the crystallographic form of the starting material, yielding solutions of defect-free, hexagonal 2D nanosheets with a well-defined size distribution. This pristine nanosheet structure results in narrow, excitation-wavelength-independent photoluminescence emission spectra. Furthermore, by controlling the aggregation state of the nanosheets, we demonstrate that the emission wavelengths can be tuned from narrow UV to broad-band white. This has potential applicability to a range of optoelectronic devices.

22. Intermediate-range solvent templating and counterion behaviour at charged carbon nanotube surfaces.

Author

Di Mino C, Headen TF, Basma NS, Buckley DJ, Cullen PL, Wilding MC, Shaffer MSP, Skipper NT, Clancy AJ, and Howard CA

Abstract

The ordering of ions and solvent molecules around nanostructures is of profound fundamental importance, from understanding biological processes to the manipulation of nanomaterials to optimizing electrochemical devices. Classical models commonly used to describe these systems treat the solvent simplistically, an approach that endures, in part, due to the extreme difficulty of attaining experimental measurements that challenge this approximation. Here we perform total neutron scattering experiments on model systems-concentrated amide solutions of negatively charged carbon nanotubes and sodium counterions-and measure remarkably complex intermediate-range molecular solvent ordering. The charged surface orders the solvents up to ∼40 Å, even beyond its dense concentric solvation shells. Notably, the molecular orientation of solvent in direct contact with the nanotube surface itself is distinct, lying near-parallel and not interacting with desolvated sodium counterions. In contrast, beyond this layer the ordering of solvent is perpendicular to the surface. Our results underscore the critical importance of multibody interactions in solvated nanoscale systems and charged surfaces, highlighting competing ion/surface solvation effects., Competing Interests: Competing interests: The authors declare no competing interests., (© 2025. The Author(s).)

Published
2025
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23. Exploiting Organometallic Chemistry to Functionalize Small Cuprous Oxide Colloidal Nanocrystals.

Author

Cowie BE, Mears KL, S'ari M, Lee JK, Briceno de Gutierrez M, Kalha C, Regoutz A, Shaffer MSP, and Williams CK

Abstract

The ligand chemistry of colloidal semiconductor nanocrystals mediates their solubility, band gap, and surface facets. Here, selective organometallic chemistry is used to prepare small, colloidal cuprous oxide nanocrystals and to control their surface chemistry by decorating them with metal complexes. The strategy is demonstrated using small (3-6 nm) cuprous oxide (Cu 2 O) colloidal nanocrystals (NC), soluble in organic solvents. Organometallic complexes are coordinated by reacting the surface Cu-OH bonds with organometallic reagents, M(C 6 F 5 ) 2 , M = Zn(II) and Co(II), at room temperature. These reactions do not disrupt the Cu 2 O crystallinity or nanoparticle size; rather, they allow for the selective coordination of a specific metal complex at the surface. Subsequently, the surface-coordinated organometallic complex is reacted with three different carboxylic acids to deliver Cu-O-Zn(O 2 CR') complexes. Selective nanocrystal surface functionalization is established using spectroscopy (IR, 19 F NMR), thermal gravimetric analyses (TGA), transmission electron microscopy (TEM, EELS), and X-ray photoelectron spectroscopy (XPS). Photoluminescence efficiency increases dramatically upon organometallic surface functionalization relative to that of the parent Cu 2 O NC, with the effect being most pronounced for Zn(II) decoration. The nanocrystal surfaces are selectively functionalized by both organic ligands and well-defined organometallic complexes; this synthetic strategy may be applicable to many other metal oxides, hydroxides, and semiconductors. In the future, it should allow NC properties to be designed for applications including catalysis, sensing, electronics, and quantum technologies.

Published
2024
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24. Examining the Quasi-Static Uniaxial Compressive Behaviour of Commercial High-Performance Epoxy Matrices.

Author

Gargiuli JF, Quino G, Board R, Griffith JC, Shaffer MSP, Trask RS, and Hamerton I

Abstract

Four commercial high-performance aerospace aromatic epoxy matrices, CYCOM ® 890, CYCOM ® 977-2, PR520, and PRISM EP2400, were cured to a standardised 2 h, 180 °C cure cycle and evaluated in quasi-static uniaxial compression, as well as by dynamic scanning calorimetry (DSC) and thermogravimetric analysis (TGA). The thermoplastic toughened CYCOM ® 977-2 formulation displayed an overall increase in true axial stress values across the entire stress-strain curve relative to the baseline CYCOM ® 890 sample. The particle-toughened PR520 sample exhibited an overall decrease in true axial stress values past the yield point of the material. The PRISM EP2400 resin, with combined toughening agents, led to true axial stress values across the entire plastic region of the stress-strain curve, which were in line with the stress values observed with the CYCOM ® 890 material. Interestingly, for all formulations, the dilation angles (associated with the volume change during plastic deformation), recorded at 0.3 plastic strain, were close to 0°, with the variations reflecting the polymer structure. Compression data collected for this series of commercial epoxy resins are in broad agreement with a selection of model epoxy resins based on di- and tetra-functional monomers, cured with polyamines or dicarboxylic anhydrides. However, the fully formulated resins demonstrate a significantly higher compressive modulus than the model resins, albeit at the expense of yield stress.

Published
2023
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25. Matched Ligands for Small, Stable Colloidal Nanoparticles of Copper, Cuprous Oxide and Cuprous Sulfide.

Author

Cowie BE, Häfele L, Phanopoulos A, Said SA, Lee JK, Regoutz A, Shaffer MSP, and Williams CK

Subjects
Ligands, Sulfides, Copper, Nanoparticles
Abstract

This work applies organometallic routes to copper(0/I) nanoparticles and describes how to match ligand chemistries with different material compositions. The syntheses involve reacting an organo-copper precursor, mesitylcopper(I) [CuMes] z (z=4, 5), at low temperatures and in organic solvents, with hydrogen, air or hydrogen sulfide to deliver Cu, Cu 2 O or Cu 2 S nanoparticles. Use of sub-stoichiometric quantities of protonated ligand (pro-ligand; 0.1-0.2 equivalents vs. [CuMes] z ) allows saturation of surface coordination sites but avoids excess pro-ligand contaminating the nanoparticle solutions. The pro-ligands are nonanoic acid (HO 2 CR 1 ), 2-[2-(2-methoxyethoxy)ethoxy]acetic acid (HO 2 CR 2 ) or di(thio)nonanoic acid, (HS 2 CR 1 ), and are matched to the metallic, oxide or sulfide nanoparticles. Ligand exchange reactions reveal that copper(0) nanoparticles may be coordinated by carboxylate or di(thio)carboxylate ligands, but Cu 2 O is preferentially coordinated by carboxylate ligands and Cu 2 S by di(thio)carboxylate ligands. This work highlights the opportunities for organometallic routes to well-defined nanoparticles and the need for appropriate ligand selection., (© 2023 The Authors. Chemistry - A European Journal published by Wiley-VCH GmbH.)

Published
2023
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26. Wet spinning imogolite nanotube fibres: an in situ process study.

Author

Moore JF, Paineau E, Launois P, and Shaffer MSP

Abstract

Imogolite nanotubes (INTs) form transparent aqueous liquid-crystalline solutions, with strong birefringence and X-ray scattering power. They provide an ideal model system for studying the assembly of one-dimensional nanomaterials into fibres, as well as offering interesting properties in their own right. Here, in situ polarised optical microscopy is used to study the wet spinning of pure INTs into fibres, illustrating the influence of process variables during extrusion, coagulation, washing and drying on both structure and mechanical properties. Tapered spinnerets were shown to be significantly more effective than thin cylindrical channels for forming homogeneous fibres; a result related to simple capillary rheology by fitting a shear thinning flow model. The washing step has a strong influence of structure and properties, combining the removal of residual counter-ions and structural relaxation to produce a less aligned, denser and more networked structure; the timescales and scaling behavior of the processes are compared quantitatively. Both strength and stiffness are higher for INT fibres with a higher packing fraction and lower degree of alignment, indicating the importance of forming a rigid jammed network to transfer stress through these porous, rigid rod assemblies. The electrostatically-stabilised, rigid rod INT solutions were successfully cross-linked using multivalent anions, providing robust gels, potentially useful in other contexts., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published
2023
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27. Platinum deposition on functionalised graphene for corrosion resistant oxygen reduction electrodes.

Author

Rubio N, Suter T, Rana Z, Clancy AJ, Masuda S, Au H, Coulter G, Sirisinudomkit P, McMillan PF, Howard CA, Mattevi C, Brett DJL, and Shaffer MSP

Abstract

Graphene-related materials are promising supports for electrocatalysts due to their stability and high surface area. Their innate surface chemistries can be controlled and tuned via functionalisation to improve the stability of both the carbon support and the metal catalyst. Functionalised graphenes were prepared using either aryl diazonium functionalisation or non-destructive chemical reduction, to provide groups adapted for platinum deposition. XPS and TGA-MS measurements confirmed the presence of polyethyleneglycol and sulfur-containing functional groups, and provided consistent values for the extent of the reactions. The deposited platinum nanoparticles obtained were consistently around 2 nm via reductive chemistry and around 4 nm via the diazonium route. Although these graphene-supported electrocatalysts provided a lower electrochemical surface area (ECSA), functionalised samples showed enhanced specific activity compared to a commercial platinum/carbon black system. Accelerated stress testing (AST) showed improved durability for the functionalised graphenes compared to the non-functionalised materials, attributed to edge passivation and catalyst particle anchoring., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published
2022
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28. Designing Structural Electrochemical Energy Storage Systems: A Perspective on the Role of Device Chemistry.

Author

Navarro-Suárez AM and Shaffer MSP

Abstract

Structural energy storage devices (SESDs), designed to simultaneously store electrical energy and withstand mechanical loads, offer great potential to reduce the overall system weight in applications such as automotive, aircraft, spacecraft, marine and sports equipment. The greatest improvements will come from systems that implement true multifunctional materials as fully as possible. The realization of electrochemical SESDs therefore requires the identification and development of suitable multifunctional structural electrodes, separators, and electrolytes. Different strategies are available depending on the class of electrochemical energy storage device and the specific chemistries selected. Here, we review existing attempts to build SESDs around carbon fiber (CF) composite electrodes, including the use of both organic and inorganic compounds to increase electrochemical performance. We consider some of the key challenges and discuss the implications for the selection of device chemistries., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Navarro-Suárez and Shaffer.)

Published
2022
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29. Effect of graphene flake size on functionalisation: quantifying reaction extent and imaging locus with single Pt atom tags.

Author

Rubio N, Au H, Coulter GO, Guetaz L, Gebel G, Mattevi C, and Shaffer MSP

Abstract

Here, the locus of functionalisation on graphene-related materials and the progress of the reaction is shown to depend strongly on the starting feedstock. Five characteristically different graphite sources were exfoliated and functionalized using a non-destructive chemical reduction method. These archetypical examples were compared via a model reaction, grafting dodecyl addends, evaluated with TGA-MS, XPS and Raman data. A general increase in grafting ratio (ranging from 1.1 wt% up to 25 wt%) and an improvement in grafting stoichiometry (C/R) were observed as flake radius decreased. Raman spectrum imaging of the functionalised natural flake graphite identified that grafting is directed towards flake edges. This behaviour was further corroborated, at atomistic resolution, by functionalising the graphene layers with bipyridine groups able to complex single platinum atoms. The distribution of these groups was then directly imaged using aberration-corrected HAADF-STEM. Platinum atoms were found to be homogeneously distributed across smaller graphenes; in contrast, a more heterogeneous distribution, with a predominance of edge grafting was observed for larger graphites. These observations show that grafting is directed towards flake edges, but not necessary at edge sites; the mechanism is attributed to the relative inaccessibility of the inner basal plane to reactive moieties, resulting in kinetically driven grafting nearer flake edges. This phenomenology may be relevant to a wide range of reactions on graphenes and other 2d materials., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published
2021
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30. Scalable Sacrificial Templating to Increase Porosity and Platinum Utilisation in Graphene-Based Polymer Electrolyte Fuel Cell Electrodes.

Author

Suter TAM, Clancy AJ, Rubio Carrero N, Heitzmann M, Guetaz L, Shearing PR, Mattevi C, Gebel G, Howard CA, Shaffer MSP, McMillan PF, and Brett DJL

Abstract

Polymer electrolyte fuel cells hold great promise for a range of applications but require advances in durability for widespread commercial uptake. Corrosion of the carbon support is one of the main degradation pathways; hence, corrosion-resilient graphene has been widely suggested as an alternative to traditional carbon black. However, the performance of bulk graphene-based electrodes is typically lower than that of commercial carbon black due to their stacking effects. This article reports a simple, scalable and non-destructive method through which the pore structure and platinum utilisation of graphene-based membrane electrode assemblies can be significantly improved. Urea is incorporated into the catalyst ink before deposition, and is then simply removed from the catalyst layer after spraying by submerging the electrode in water. This additive hinders graphene restacking and increases porosity, resulting in a significant increase in Pt utilisation and current density. This technique does not require harsh template etching and it represents a pathway to significantly improve graphene-based electrodes by introducing hierarchical porosity using scalable liquid processes.

Published
2021
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31. Defect-Free Single-Layer Graphene by 10 s Microwave Solid Exfoliation and Its Application for Catalytic Water Splitting.

Author

Bayazit MK, Xiong L, Jiang C, Moniz SJA, White E, Shaffer MSP, and Tang J

Abstract

Mass production of defect-free single-layer graphene flakes (SLGFs) by a cost-effective approach is still very challenging. Here, we report such single-layer graphene flakes (SLGFs) (>90%) prepared by a nondestructive, energy-efficient, and easy up-scalable physical approach. These high-quality graphene flakes are attributed to a novel 10 s microwave-modulated solid-state approach, which not only fast exfoliates graphite in air but also self-heals the surface of graphite to remove the impurities. The fabricated high-quality graphene films (∼200 nm) exhibit a sheet resistance of ∼280 Ω/sq without any chemical or physical post-treatment. Furthermore, graphene-incorporated Ni-Fe electrodes represent a remarkable ∼140 mA/cm 2 current for the catalytic water oxidation reaction compared with the pristine Ni-Fe electrode (∼10 mA/cm 2 ) and a 120 mV cathodic shift in onset potential under identical experimental conditions, together with a faradic efficiency of >90% for an ideal ratio of H 2 and O 2 production from water. All these excellent performances are attributed to extremely high conductivity of the defect-free graphene flakes.

Published
2021
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32. Continuous Binder-Free Fibers of Pure Imogolite Nanotubes.

Author

Moore JF, Paineau E, Launois P, and Shaffer MSP

Abstract

Imogolite nanotubes (INTs) display a range of useful properties and provide an ideal material system to study the assembly of nanomaterials into macroscopic fibers. A method of wet spinning pure, binder-free imogolite fibers has been developed using double-walled germanium imogolite nanotubes. The nanotube aspect ratio can be controlled during the initial synthesis and is critical to the spinning process. Fibers made from short nanotubes (<100 nm) have very low gel strengths, while dopes with longer nanotubes (500-1000 nm) are readily spinnable. The tensile behavior of the resulting imogolite nanotube fibers is strongly influenced by relative humidity (RH), with a modulus of 30 GPa at 10% RH compared to 2.8 GPa at 85% RH, as well as a change in failure mode. This result highlights the importance of inter-nanotube interactions in such assemblies and provides a useful strategy for further exploration. Interestingly, in the absence of a matrix phase, a degree of misorientation appears to improve load transfer between the individual INTs within the porous fiber, likely due to an increase in the number of interparticle contacts. Imogolite nanotubes are an appealing analogue to other nanotube fiber systems, and it is hoped that learnings from this system can also be used to improve carbon nanotube fibers.

Published
2021
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33. Understanding and controlling the covalent functionalisation of graphene.

Author

Clancy AJ, Au H, Rubio N, Coulter GO, and Shaffer MSP

Abstract

Chemical functionalisation is one of the most active areas of graphene research, motivated by fundamental science, the opportunities to adjust or supplement intrinsic properties, and the need to assemble materials for a broad array of applications. Historically, the primary consideration has been the degree of functionalisation but there is growing interest in understanding how and where modification occurs. Reactions may proceed preferentially at edges, defects, or on graphitic faces; they may be correlated, uncorrelated, or anti-correlated with previously grafted sites. A detailed collation of existing literature data indicates that steric effects play a strong role in limiting the extent of reaction. However, the pattern of functionalisation may have important effects on the resulting properties. This article addresses the unifying principles of current graphene functionalisation technologies, with emphasis on understanding and controlling the locus of functionalisation.

Published
2020
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34. Inorganic Nanotube Mesophases Enable Strong Self-Healing Fibers.

Author

Lee WJ, Paineau E, Anthony DB, Gao Y, Leese HS, Rouzière S, Launois P, and Shaffer MSP

Abstract

The assembly of one-dimensional nanomaterials into macroscopic fibers can improve mechanical as well as multifunctional performance. Double-walled aluminogermanate imogolite nanotubes are geo-inspired analogues of carbon nanotubes, synthesized at low temperature, with complementary properties. Here, continuous imogolite-based fibers are wet-spun within a poly(vinyl alcohol) matrix. The lyotropic liquid crystallinity of the system produces highly aligned fibers with tensile stiffness and strength up to 24.1 GPa (14.1 N tex -1 ) and 0.8 GPa (0.46 N tex -1 ), respectively. Significant enhancements over the pure polymer control are quantitatively attributed to both matrix refinement and direct nanoscale reinforcement, by fitting an analytical model. Most intriguingly, imogolite-based fibers show a high degree of healability via evaporation-induced self-assembly, recovering up to 44% and 19% of the original fiber tensile stiffness and strength, respectively. This recovery at high absolute strength highlights a general strategy for the development of high-performance healable fibers relevant to composite structures and other applications.

Published
2020
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35. Thermal Decomposition of Ternary Sodium Graphite Intercalation Compounds.

Author

Au H, Rubio N, Buckley DJ, Mattevi C, and Shaffer MSP

Abstract

Graphite intercalation compounds (GICs) are often used to produce exfoliated or functionalised graphene related materials (GRMs) in a specific solvent. This study explores the formation of the Na-tetrahydrofuran (THF)-GIC and a new ternary system based on dimethylacetamide (DMAc). Detailed comparisons of in situ temperature dependent XRD with TGA-MS and Raman measurements reveal a series of dynamic transformations during heating. Surprisingly, the bulk of the intercalation compound is stable under ambient conditions, trapped between the graphene sheets. The heating process drives a reorganisation of the solvent and Na molecules, then an evaporation of the solvent; however, the solvent loss is arrested by restacking of the graphene layers, leading to trapped solvent bubbles. Eventually, the bubbles rupture, releasing the remaining solvent and creating expanded graphite. These trapped dopants may provide useful property enhancements, but also potentially confound measurements of grafting efficiency in liquid-phase covalent functionalization experiments on 2D materials., (© 2020 The Authors. Published by Wiley-VCH Verlag GmbH & Co. KGaA.)

Published
2020
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36. Antibacterial Surfaces with Activity against Antimicrobial Resistant Bacterial Pathogens and Endospores.

Author

Sehmi SK, Lourenco C, Alkhuder K, Pike SD, Noimark S, Williams CK, Shaffer MSP, Parkin IP, MacRobert AJ, and Allan E

Subjects
Anti-Bacterial Agents pharmacology, Cross Infection prevention & control, Drug Resistance, Multiple, Bacterial, Gentian Violet pharmacology, Humans, Light, Microbial Sensitivity Tests, Nanoparticles, Polyurethanes, Zinc Oxide pharmacology, Anti-Infective Agents pharmacology, Clostridioides difficile drug effects, Escherichia coli drug effects, Methicillin-Resistant Staphylococcus aureus drug effects, Pseudomonas aeruginosa drug effects
Abstract

Hospital-acquired bacterial infections are a significant burden on healthcare systems worldwide causing an increased duration of hospital stays and prolonged patient suffering. We show that polyurethane containing crystal violet (CV) and 3-4 nm zinc oxide nanoparticles (ZnO NPs) possesses excellent bactericidal activity against hospital-acquired pathogens including multidrug resistant Escherichia coli ( E. coli ), Pseudomonas aeruginosa , methicillin-resistant Staphylococcus aureus (MRSA), and even highly resistant endospores of Clostridioides (Clostridium) difficile . Importantly, we used clinical isolates of bacterial strains, a protocol to mimic the environmental conditions of a real exposure in the healthcare setting, and low light intensity equivalent to that encountered in UK hospitals (∼500 lux). Our data shows that ZnO NPs enhance the photobactericidal activity of CV under low intensity light even with short exposure times, and we show that this involves both Type I and Type II photochemical pathways. Interestingly, polyurethane containing ZnO NPs alone showed significant bactericidal activity in the dark against one strain of E. coli , indicating that the NPs possess both light-activated synergistic activity with CV and inherent bactericidal activity that is independent of light. These new antibacterial polymers are potentially useful in healthcare facilties to reduce the transmission of pathogens between people and the environment.

Published
2020
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37. Quantification of blood-brain barrier transport and neuronal toxicity of unlabelled multiwalled carbon nanotubes as a function of surface charge.

Author

Gonzalez-Carter D, Goode AE, Kiryushko D, Masuda S, Hu S, Lopes-Rodrigues R, Dexter DT, Shaffer MSP, and Porter AE

Subjects
Animals, Biological Transport, Blood-Brain Barrier ultrastructure, Cell Line, Transformed, Cell Membrane ultrastructure, Endothelial Cells ultrastructure, Humans, Nanotubes, Carbon ultrastructure, Rats, Blood-Brain Barrier metabolism, Cell Membrane metabolism, Endothelial Cells metabolism, Materials Testing, Nanotubes, Carbon chemistry, Transcytosis drug effects
Abstract

Nanoparticles capable of penetrating the blood-brain barrier (BBB) will greatly advance the delivery of therapies against brain disorders. Carbon nanotubes hold great potential as delivery vehicles due to their high aspect-ratio and cell-penetrating ability. Studies have shown multiwalled carbon nanotubes (MWCNT) cross the BBB, however they have largely relied on labelling methods to track and quantify transport, or on individual electron microscopy images to qualitatively assess transcytosis. Therefore, new direct and quantitative methods, using well-defined and unlabelled MWCNT, are needed to compare BBB translocation of different MWCNT types. Using highly controlled anionic (-), cationic (+) and non-ionic (0) functionalized MWCNT (fMWCNT), we correlate UV-visible spectroscopy with quantitative transmission electron microscopy, quantified from c. 270 endothelial cells, to examine cellular uptake, BBB transport and neurotoxicity of unlabelled fMWCNT. Our results demonstrate that: (i) a large fraction of cationic and non-ionic, but not anionic fMWCNT become trapped at the luminal brain endothelial cell membrane; (ii) despite high cell association, fMWCNT uptake by brain endothelial cells is low (<1.5% ID) and does not correlate with BBB translocation, (iii) anionic fMWCNT have highest transport levels across an in vitro model of the human BBB compared to non-ionic or cationic nanotubes; and (iv) fMWCNT are not toxic to hippocampal neurons at relevant abluminal concentrations; however, fMWCNT charge has an effect on carbon nanotube neurotoxicity at higher fMWCNT concentrations. This quantitative combination of microscopy and spectroscopy, with cellular assays, provides a crucial strategy to predict brain penetration efficiency and neurotoxicity of unlabelled MWCNT and other nanoparticle technologies relevant to human health.

Published
2019
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38. One-Dimensional Pnictogen Allotropes inside Single-Wall Carbon Nanotubes.

Author

Hart M, Chen J, Michaelides A, Sella A, Shaffer MSP, and Salzmann CG

Abstract

The discovery of phosphorene, a single layer of black phosphorus, has accelerated the investigation of pnictogen nanomaterials, leading to the recent identification of arsenene and antimonene. These two-dimensional nanomaterials display physical properties superior to those of graphene for some applications. Recently, single-wall carbon nanotubes (SWCNTs) have been filled with P 4 molecules from the melt and As 4 molecules from the vapor phase. Confined within SWCNTs, polymerization reactions yielded new one-dimensional pnictogen allotropes. Here, we show using high-resolution electron microscopy that such nanostructures can also be observed upon filling SWCNTs from the vapor phase using red phosphorus as the source material. Using larger-diameter SWCNTs, the vapor phase favors the formation of double-stranded phosphorus zigzag ladders observed here for the first time. Overall, however, SWCNTs were generally found to fill more efficiently with liquid phosphorus; substantial decreases in the filling yields were observed for both phosphorus and arsenic filling of narrow SWCNTs using the vapor route. Attempts to extend the pnitogen series using molten antimony gave very low filling yields. However, the antimony zigzag ladder was observed on two occasions, suggesting that this structural motif dominates across the pnictogens. Computational predictions of the encapsulation energies of the various pnictogen nanostructures are consistent with the observed experimental trends, and band gap calculations predict that the single-stranded zigzag chains of all investigated pnictogens are fully metallic. Using SWCNTs with diameters of >1.5 nm revealed a plethora of complex new phosphorus nanostructures, which highlights an exciting new avenue for future work in this area.

Published
2019
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39. Vapour-liquid-solid growth of ZnO-ZnMgO core-shell nanowires by gold-catalysed molecular beam epitaxy.

Author

Kennedy OW, White ER, Shaffer MSP, and Warburton PA

Abstract

Nanowire heterostructures, combining multiple phases within a single nanowire, modify functional properties and offer a platform for novel device development. Here, ZnO/ZnMgO core-shell nanowires are grown by molecular beam epitaxy. At growth temperatures above 750 °C, Mg diffuses into ZnO making heterostructure growth impossible; at lower shell-growth temperatures (500 °C), the core-shell structure is retained. Even very thin ZnMgO shells show increased intensity photoluminescence (PL) across the ZnO band-gap and a suppression in defect-related PL intensity, relative to plain ZnO nanowires. EDX measurements on shell thickness show a correlation between shell thickness and core diameter which is explained by a simple growth model.

Published
2019
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40. Mapping the Origins of Luminescence in ZnO Nanowires by STEM-CL.

Author

Kennedy OW, White ER, Howkins A, Williams CK, Boyd IW, Warburton PA, and Shaffer MSP

Abstract

In semiconductor nanowires, understanding both the sources of luminescence (excitonic recombination, defects, etc.) and the distribution of luminescent centers (be they uniformly distributed, or concentrated at structural defects or at the surface) is important for synthesis and applications. We develop scanning transmission electron microscopy-cathodoluminescence (STEM-CL) measurements, allowing the structure and cathodoluminescence (CL) of single ZnO nanowires to be mapped at high resolution. Using a CL pixel resolution of 10 nm, variations of the CL spectra within such nanowires in the direction perpendicular to the nanowire growth axis are identified for the first time. By comparing the local CL spectra with the bulk photoluminescence spectra, the CL spectral features are assigned to internal and surface defect structures. Hyperspectral CL maps are deconvolved to enable characteristic spectral features to be spatially correlated with structural features within single nanowires. We have used these maps to show that the spatial distribution of these defects correlates well with regions that show an increased rate of nonradiative transitions.

Published
2019
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41. Real-time mechanistic study of carbon nanotube anion functionalisation through open circuit voltammetry.

Author

Clancy AJ, Sirisinudomkit P, Anthony DB, Thong AZ, Greenfield JL, Salaken Singh MK, and Shaffer MSP

Abstract

The mechanism of the functionalisation of reduced single walled carbon nanotubes with organobromides was monitored by open circuit voltammetry throughout the reaction and further elucidated through a series of comparative reactions. The degree of functionalisation was mapped against the reagent reduction potential, degree of electron donation of substituents (Hammett parameter), and energies calculated, ab initio , for dissociation and heterolytic cleavage of the C-Br bond. In contrast to the previously assumed reduction/homolytic cleavage mechanism, the reaction was shown to consist of a rapid association of carbon-halide bond to the reduced nanotube as a complex, displacing surface-condensed countercations, leading to an initial increase in the net nanotube surface negative charge. The complex subsequently slowly degrades through charge transfer from the reduced single-walled carbon nanotube to the organobromide, utilizing charge, and the carbon-halide bond breaks heterolytically. Electron density on the C-Br bond in the initial reagent is the best predictor for degree of functionalisation, with more electron donating substituents increasing the degree of functionalisation. Both the mechanism and the new application of OCV to study such reactions are potentially relevant to a wide range of related systems.

Published
2019
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42. Depleting Depletion: Maintaining Single-Walled Carbon Nanotube Dispersions after Graft-To Polymer Functionalization.

Author

Clancy AJ, Leese HS, Rubio N, Buckley DJ, Greenfield JL, and Shaffer MSP

Abstract

Grafting polymers onto single-walled carbon nanotubes (SWCNTs) usefully alters properties but does not typically yield stable, solvated species directly. Despite the expectation of steric stabilization, a damaging (re)dispersion step is usually necessary. Here, poly(vinyl acetate)s (PVAc's) of varying molecular weights are grafted to individualized, reduced SWCNTs at different concentrations to examine the extent of reaction and degree of solvation. The use of higher polymer concentrations leads to an increase in grafting ratio (weight fraction of grafted polymer relative to the SWCNT framework), approaching the limit of random sequentially adsorbed Flory "mushrooms" on the surface. However, at higher polymer concentrations, a larger percentage of SWCNTs precipitate during the reaction; an effect which is more significant for larger weight polymers. The precipitation is attributed to depletion interactions generated by ungrafted homopolymer overcoming Coulombic repulsion of adjacent like-charged SWCNTs; a simple model is proposed. Larger polymers and greater degrees of functionalization favor stable solvation, but larger and more concentrated homopolymers increase depletion aggregation. By using low concentrations (25 μM) of larger molecular weight PVAc (10 kDa), up to 65% of grafted SWCNTs were retained in solution (at 65 μg mL -1 ) directly after the reaction.

Published
2018
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43. Local Structure and Polar Order in Liquid N-Methyl-2-pyrrolidone (NMP).

Author

Basma NS, Headen TF, Shaffer MSP, Skipper NT, and Howard CA

Abstract

N-Methyl-2-pyrrolidone (NMP) is an exceptional solvent, widely used in industry and for nanomaterials processing. Yet despite its ubiquity, its liquid structure, which ultimately dictates its solvation properties, is not fully known. Here, neutron scattering is used to determine NMP's structure in unprecedented detail. Two dominant nearest-neighbor arrangements are found, where rings are parallel or perpendicular. However, compared with related solvents, NMP has a relatively large population of parallel approaches, similar only to benzene, despite its nonaromaticity and the presence of the normally structure-reducing methyl group. This arrangement is underpinned by NMP's dipole moment, which has a profound effect on its structure: nearest-neighbor molecules arrange in an antiparallel but offset fashion. This polar-induced order extends beyond the first solvation shell, resulting in ordered trimers that reach the nanometer range. The degree of order and balance of interactions rationalize NMP's high boiling point and versatile capabilities to solvate both charged and uncharged species.

Published
2018
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44. Fast Exfoliation and Functionalisation of Two-Dimensional Crystalline Carbon Nitride by Framework Charging.

Author

Jia J, White ER, Clancy AJ, Rubio N, Suter T, Miller TS, McColl K, McMillan PF, Brázdová V, Corà F, Howard CA, Law RV, Mattevi C, and Shaffer MSP

Abstract

Two-dimensional (2D) layered graphitic carbon nitride (gCN) nanosheets offer intriguing electronic and chemical properties. However, the exfoliation and functionalisation of gCN for specific applications remain challenging. We report a scalable one-pot reductive method to produce solutions of single- and few-layer 2D gCN nanosheets with excellent stability in a high mass yield (35 %) from polytriazine imide. High-resolution imaging confirmed the intact crystalline structure and identified an AB stacking for gCN layers. The charge allows deliberate organic functionalisation of dissolved gCN, providing a general route to adjust their properties., (© 2018 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published
2018
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45. One-Dimensional Arsenic Allotropes: Polymerization of Yellow Arsenic Inside Single-Wall Carbon Nanotubes.

Author

Hart M, Chen J, Michaelides A, Sella A, Shaffer MSP, and Salzmann CG

Abstract

The pnictogen nanomaterials, including phosphorene and arsenene, display remarkable electronic and chemical properties. Yet, the structural diversity of these main group elements is still poorly explored. Here we fill single-wall carbon nanotubes with elemental arsenic from the vapor phase. Using electron microscopy, we find chains of highly reactive As 4 molecules as well as two new one-dimensional allotropes of arsenic: a single-stranded zig-zag chain and a double-stranded zig-zag ladder. These linear structures are important intermediates between the gas-phase clusters of arsenic and the extended sheets of arsenene. Raman spectroscopy indicates weak electronic interaction between the arsenic and the nanotubes which implies that the formation of the new allotropes is driven primarily by the geometry of the confinement. The relative stabilities of the new arsenic structures are estimated computationally. Band-gap calculations predict that the insulating As 4 chains become semiconducting, once converted to the zig-zag ladder, and form a fully metallic allotrope of arsenic as the zig-zag chain., (© 2018 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published
2018
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46. Charged Carbon Nanomaterials: Redox Chemistries of Fullerenes, Carbon Nanotubes, and Graphenes.

Author

Clancy AJ, Bayazit MK, Hodge SA, Skipper NT, Howard CA, and Shaffer MSP

Abstract

Since the discovery of buckminsterfullerene over 30 years ago, sp 2 -hybridised carbon nanomaterials (including fullerenes, carbon nanotubes, and graphene) have stimulated new science and technology across a huge range of fields. Despite the impressive intrinsic properties, challenges in processing and chemical modification continue to hinder applications. Charged carbon nanomaterials (CCNs), formed via the reduction or oxidation of these carbon nanomaterials, facilitate dissolution, purification, separation, chemical modification, and assembly. This approach provides a compelling alternative to traditional damaging and restrictive liquid phase exfoliation routes. The broad chemistry of CCNs not only provides a versatile and potent means to modify the properties of the parent nanomaterial but also raises interesting scientific issues. This review focuses on the fundamental structural forms: buckminsterfullerene, single-walled carbon nanotubes, and single-layer graphene, describing the generation of their respective charged nanocarbon species, their interactions with solvents, chemical reactivity, specific (opto)electronic properties, and emerging applications.

Published
2018
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47. Multimetallic Microparticles Increase the Potency of Rifampicin against Intracellular Mycobacterium tuberculosis.

Author

Ellis T, Chiappi M, García-Trenco A, Al-Ejji M, Sarkar S, Georgiou TK, Shaffer MSP, Tetley TD, Schwander S, Ryan MP, and Porter AE

Subjects
Antitubercular Agents chemistry, Cell Line, Cell Membrane drug effects, Cell Survival drug effects, Dose-Response Relationship, Drug, Humans, Macrophages drug effects, Microbial Sensitivity Tests, Mycobacterium tuberculosis cytology, Rifampin chemistry, Structure-Activity Relationship, Zinc Oxide chemical synthesis, Antitubercular Agents pharmacology, Mycobacterium tuberculosis drug effects, Nanoparticles chemistry, Rifampin pharmacology, Silver chemistry, Zinc Oxide chemistry
Abstract

Mycobacterium tuberculosis ( M.tb) has the extraordinary ability to adapt to the administration of antibiotics through the development of resistance mechanisms. By rapidly exporting drugs from within the cytosol, these pathogenic bacteria diminish antibiotic potency and drive the presentation of drug-tolerant tuberculosis (TB). The membrane integrity of M.tb is pivotal in retaining these drug-resistant traits. Silver (Ag) and zinc oxide (ZnO) nanoparticles (NPs) are established antimicrobial agents that effectively compromise membrane stability, giving rise to increased bacterial permeability to antibiotics. In this work, biodegradable multimetallic microparticles (MMPs), containing Ag NPs and ZnO NPs, were developed for use in pulmonary delivery of antituberculous drugs to the endosomal system of M.tb-infected macrophages. Efficient uptake of MMPs by M.tb-infected THP1 cells was demonstrated using an in vitro macrophage infection model, with direct interaction between MMPs and M.tb visualized with the use of electron FIB-SEM tomography. The release of Ag NPs and ZnO NPs within the macrophage endosomal system increased the potency of the model antibiotic rifampicin by as much as 76%, realized through an increase in membrane disorder of intracellular M.tb. MMPs were effective at independently driving membrane destruction of extracellular bacilli located at the exterior face of THP1 macrophages. This MMP system presents as an effective drug delivery vehicle that could be used for the transport of antituberculous drugs such as rifampicin to infected alveolar macrophages, while increasing drug potency. By increasing M.tb membrane permeability, such a system may prove effectual in improving treatment of drug-susceptible TB in addition to M.tb strains considered drug-resistant.

Published
2018
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48. Rectification and negative differential resistance via orbital level pinning.

Author

Thong AZ, Shaffer MSP, and Horsfield AP

Abstract

A donor-acceptor system, 4-thiophenyl-azafulleroid (4TPA-C 60 ), is investigated at the point of HOMO/LUMO resonance and beyond to understand how negative differential resistance (NDR) features may be observed in such systems. Our previous investigation showed that charge transfer between the occupied and unoccupied states at resonance hindered crossing of the HOMO and LUMO levels, thus preventing the formation of an NDR feature. In this work, it is shown that the negative differential resistance feature of 4TPA-C 60 can be tailored based on the couplings at the metal/molecule interface. Ab initio calculations show that limited charge extraction from atomically sharp contacts results in a HOMO-LUMO pinning effect which delays the onset of the NDR feature. Subsequent unpinning of the states can only occur when additional charge extraction channels enter the bias window, highlighting an important role which non-frontier states play in charge transport. The proposed charge transfer mechanism is then exploited by introducing a fluorine atom into the C 60 cage to tune the energies of the acceptor, and narrow the width of the current peak. These findings not only demonstrate the importance of the metal/molecule interface in the design of molecular electronic architectures but also serve to inform future design of molecular diodes and RTDs.

Published
2018
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49. Mechanistic link between diesel exhaust particles and respiratory reflexes.

Author

Robinson RK, Birrell MA, Adcock JJ, Wortley MA, Dubuis ED, Chen S, McGilvery CM, Hu S, Shaffer MSP, Bonvini SJ, Maher SA, Mudway IS, Porter AE, Carlsten C, Tetley TD, and Belvisi MG

Subjects
Aged, Animals, Female, Guinea Pigs, Humans, Male, Mice, Middle Aged, Air Pollutants toxicity, Asthma chemically induced, Asthma metabolism, Asthma pathology, Asthma physiopathology, Bronchial Spasm chemically induced, Bronchial Spasm metabolism, Bronchial Spasm pathology, Bronchial Spasm physiopathology, Gene Expression Regulation drug effects, Particulate Matter toxicity, Reflex drug effects, Vehicle Emissions
Abstract

Background: Diesel exhaust particles (DEPs) are a major component of particulate matter in Europe's largest cities, and epidemiologic evidence links exposure with respiratory symptoms and asthma exacerbations. Respiratory reflexes are responsible for symptoms and are regulated by vagal afferent nerves, which innervate the airway. It is not known how DEP exposure activates airway afferents to elicit symptoms, such as cough and bronchospasm., Objective: We sought to identify the mechanisms involved in activation of airway sensory afferents by DEPs., Methods: In this study we use in vitro and in vivo electrophysiologic techniques, including a unique model that assesses depolarization (a marker of sensory nerve activation) of human vagus., Results: We demonstrate a direct interaction between DEP and airway C-fiber afferents. In anesthetized guinea pigs intratracheal administration of DEPs activated airway C-fibers. The organic extract (DEP-OE) and not the cleaned particles evoked depolarization of guinea pig and human vagus, and this was inhibited by a transient receptor potential ankyrin-1 antagonist and the antioxidant N-acetyl cysteine. Polycyclic aromatic hydrocarbons, major constituents of DEPs, were implicated in this process through activation of the aryl hydrocarbon receptor and subsequent mitochondrial reactive oxygen species production, which is known to activate transient receptor potential ankyrin-1 on nociceptive C-fibers., Conclusions: This study provides the first mechanistic insights into how exposure to urban air pollution leads to activation of guinea pig and human sensory nerves, which are responsible for respiratory symptoms. Mechanistic information will enable the development of appropriate therapeutic interventions and mitigation strategies for those susceptible subjects who are most at risk., (Copyright © 2017 The Authors. Published by Elsevier Inc. All rights reserved.)

Published
2018
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50. "Brick-and-Mortar" Nanostructured Interphase for Glass-Fiber-Reinforced Polymer Composites.

Author

De Luca F, Sernicola G, Shaffer MSP, and Bismarck A

Abstract

The fiber-matrix interface plays a critical role in determining composite mechanical properties. While a strong interface tends to provide high strength, a weak interface enables extensive debonding, leading to a high degree of energy absorption. Balancing these conflicting requirements by engineering composite interfaces to improve strength and toughness simultaneously still remains a great challenge. Here, a nanostructured fiber coating was realized to manifest the critical characteristics of natural nacre, at a reduced length scale, consistent with the surface curvature of fibers. The new interphase contains a high proportion (∼90 wt %) of well-aligned inorganic platelets embedded in a polymer; the window of suitable platelet dimensions is very narrow, with an optimized platelet width and thickness of about 130 and 13 nm, respectively. An anisotropic, nanostructured coating was uniformly and conformally deposited onto a large number of 9 μm diameter glass fibers, simultaneously, using self-limiting layer-by-layer assembly (LbL); this parallel approach demonstrates a promising strategy to exploit LbL methods at scale. The resulting nanocomposite interphase, primarily loaded in shear, provides new mechanisms for stress dissipation and plastic deformation. The energy released by fiber breakage in tension appear to spread and dissipate within the nanostructured interphase, accompanied by stable fiber slippage, while the interfacial strength was improved up to 30%.

Published
2018
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