Full deflection profile calculation and Young's modulus optimisation for engineered high performance materials.

New engineered materials have critical applications in different fields in medicine, engineering and technology but their enhanced mechanical performances are significantly affected by the microstructural design and the sintering process used in their manufacture. This work introduces (i) a methodology for the calculation of the full deflection profile from video recordings of bending tests, (ii) an optimisation algorithm for the characterisation of Young's modulus, (iii) a quantification of the effects of optical distortions and (iv) a comparison with other standard tests. The results presented in this paper show the capabilities of this procedure to evaluate the Young's modulus of highly stiff materials with greater accuracy than previously possible with bending tests, by employing all the available information from the video recording of the tests. This methodology extends to this class of materials the possibility to evaluate both the elastic modulus and the tensile strength with a single mechanical test, without the need for other experimental tools.

PFG NMR and Bayesian analysis to characterise non-Newtonian fluids.

Many industrial flow processes are sensitive to changes in the rheological behaviour of process fluids, and there therefore exists a need for methods that provide online, or inline, rheological characterisation necessary for process control and optimisation over timescales of minutes or less. Nuclear magnetic resonance (NMR) offers a non-invasive technique for this application, without limitation on optical opacity. We present a Bayesian analysis approach using pulsed field gradient (PFG) NMR to enable estimation of the rheological parameters of Herschel-Bulkley fluids in a pipe flow geometry, characterised by a flow behaviour index n, yield stress τ0, and consistency factor k, by analysis of the signal in q-space. This approach eliminates the need for velocity image acquisition and expensive gradient hardware. We investigate the robustness of the proposed Bayesian NMR approach to noisy data and reduced sampling using simulated NMR data and show that even with a signal-to-noise ratio (SNR) of 100, only 16 points are required to be sampled to provide rheological parameters accurate to within 2% of the ground truth. Experimental validation is provided through an experimental case study on Carbopol 940 solutions (model Herschel-Bulkley fluids) using PFG NMR at a 1H resonance frequency of 85.2MHz; for SNR>1000, only 8 points are required to be sampled. This corresponds to a total acquisition time of <60s and represents an 88% reduction in acquisition time when compared to MR flow imaging. Comparison of the shear stress-shear rate relationship, quantified using Bayesian NMR, with non-Bayesian NMR methods demonstrates that the Bayesian NMR approach is in agreement with MR flow imaging to within the accuracy of the measurement. Furthermore, as we increase the concentration of Carbopol 940 we observe a change in rheological characteristics, probably due to shear history-dependent behaviour and the different geometries used. This behaviour highlights the need for online, or inline, rheological characterisation in industrial process applications.

Structure and dynamics of aqueous 2-propanol: a THz-TDS, NMR and neutron diffraction study.

Aqueous liquid mixtures, in particular, those involving amphiphilic species, play an important role in many physical, chemical and biological processes. Of particular interest are alcohol/water mixtures; however, the structural dynamics of such systems are still not fully understood. Herein, a combination of terahertz time-domain spectroscopy (THz-TDS) and NMR relaxation time analysis has been applied to investigate 2-propanol/water mixtures across the entire composition range; while neutron diffraction studies have been carried out at two specific concentrations. Excellent agreement is seen between the techniques with a maximum in both the relative absorption coefficient and the activation energy to molecular motion occurring at ∼90 mol% H2O. Furthermore, this is the same value at which well-established excess thermodynamic functions exhibit a maximum/minimum. Additionally, both neutron diffraction and THz-TDS have been used to provide estimates of the size of the hydration shell around 2-propanol in solution. Both methods determine that between 4 and 5 H2O molecules per 2-propanol are found in the 2-propanol/water clusters at 90 mol% H2O. Based on the acquired data, a description of the structure of 2-propanol/water across the composition range is presented.

Characterising the rheology of non-Newtonian fluids using PFG-NMR and cumulant analysis.

Conventional rheological characterisation using nuclear magnetic resonance (NMR) typically utilises spatially-resolved measurements of velocity. We propose a new approach to rheometry using pulsed field gradient (PFG) NMR which readily extends the application of MR rheometry to single-axis gradient hardware. The quantitative use of flow propagators in this application is challenging because of the introduction of artefacts during Fourier transform, which arise when realistic sampling strategies are limited by experimental and hardware constraints and when particular spatial and temporal resolution are required. The method outlined in this paper involves the cumulant analysis of the acquisition data directly, thereby preventing the introduction of artefacts and reducing data acquisition times. A model-dependent approach is developed to enable the pipe-flow characterisation of fluids demonstrating non-Newtonian power-law rheology, involving the use of an analytical expression describing the flow propagator in terms of the flow behaviour index. The sensitivity of this approach was investigated and found to be robust to the signal-to-noise ratio (SNR) and number of acquired data points, enabling an increase in temporal resolution defined by the SNR. Validation of the simulated results was provided by an experimental case study on shear-thinning aqueous xanthan gum solutions, whose rheology could be accurately characterised using a power-law model across the experimental shear rate range of 1-100 s(-1). The flow behaviour indices calculated using this approach were observed to be within 8% of those obtained using spatially-resolved velocity imaging and within 5% of conventional rheometry. Furthermore, it was shown that the number of points sampled could be reduced by a factor of 32, when compared to the acquisition of a volume-averaged flow propagator with 128 gradient increments, without negatively influencing the accuracy of the characterisation, reducing the acquisition time to only 3% of its original value.

Application of Positron Emission Particle Tracking (PEPT) to validate a Discrete Element Method (DEM) model of granular flow and mixing in the Turbula mixer.

The laboratory-scale Turbula mixer comprises a simple cylindrical vessel that moves with a complex, yet periodic 3D motion comprising of rotation, translation and inversion. Arising from this complexity, relatively few studies to obtain fundamental understanding of particle motion and mixing mechanisms have been reported. Particle motion within a cylindrical vessel of a Turbula mixer has been measured for 2mm glass spheres using Positron Emission Particle Tracking (PEPT) in a 2l blending mixing vessel at 50% fill level. These data are compared to results from Discrete Element Method (DEM) simulations previously published by the authors. PEPT mixing experiments, using a single particle tracer, gave qualitatively similar trends to the DEM predictions for axial and radial dispersion as well as for the axial displacement statistics at different operational speeds. Both experimental and simulation results indicate a minimum mixing efficiency at ca. 46 rpm. The occupancy plots also show a non-linear relationship with the operating speed. These results add further evidence to a transition between two flow and mixing regimes. Despite the similarity in overall flow and mixing behaviour measured and predicted, including the mixing speed at which the flow behaviour transition occurs, a systematic offset between measured and predicted result is observed.

Tunable gold catalysts for selective hydrocarbon oxidation under mild conditions.

Oxidation is an important method for the synthesis of chemical intermediates in the manufacture of high-tonnage commodities, high-value fine chemicals, agrochemicals and pharmaceuticals: but oxidations are often inefficient. The introduction of catalytic systems using oxygen from air is preferred for 'green' processing. Gold catalysis is now showing potential in selective redox processes, particularly for alcohol oxidation and the direct synthesis of hydrogen peroxide. However, a major challenge that persists is the synthesis of an epoxide by the direct electrophilic addition of oxygen to an alkene. Although ethene is epoxidized efficiently using molecular oxygen with silver catalysts in a large-scale industrial process, this is unique because higher alkenes can only be effectively epoxidized using hydrogen peroxide, hydroperoxides or stoichiometric oxygen donors. Here we show that nanocrystalline gold catalysts can provide tunable active catalysts for the oxidation of alkenes using air, with exceptionally high selectivity to partial oxidation products ( approximately 98%) and significant conversions. Our finding significantly extends the discovery by Haruta that nanocrystalline gold can epoxidize alkenes when hydrogen is used to activate the molecular oxygen; in our case, no sacrificial reductant is needed. We anticipate that our finding will initiate attempts to understand more fully the mechanism of oxygen activation at gold surfaces, which might lead to commercial exploitation of the high redox activity of gold nanocrystals.

Substrate dependence of human neutrophil protein kinase C.

To determine the contribution of phosphate acceptor substrate to the pattern of activity of calcium-dependent, phospholipid-sensitive protein kinase (protein kinase C, PKC), we assayed cytosolic and particulate PKC activity for histone, troponin, myosin light chain (MLC), and endogenous cellular proteins in human neutrophils stimulated with phorbol myristate acetate (PMA), the chemotactic peptide n-formyl-methionyl-leucyl-phenylalanine (FMLP) and synergistic stimulation with both agonists. In general, phosphotransferase activity in neutrophil subfractions toward troponin and endogenous proteins paralleled that toward histone, but MLC was a poor substrate for PKC and the pattern of phosphotransferase activity differed from that seen with the other substrates. Furthermore, the phosphorylation of endogenous neutrophil cytosolic proteins increased significantly after stimulation with FMLP, suggesting an endogenous cytosolic substrate(s) which increased in concentration following stimulation. We conclude that histone is a useful phosphate acceptor for study of PKC activity in human neutrophils, but substrate variability occurs and may influence interpretation of results in assays of PKC activity.

Chemotactic peptide enhancement of phorbol ester-induced protein kinase C activity in human neutrophils.

Chemotactic factors and phorbol esters may act synergistically to evoke neutrophil responses, but the mechanism of such interaction is not entirely clear. We investigated the combined effects of the chemotactic peptide n-formyl-methionyl-leucyl-phenylalanine (FMLP) and phorbol myristate acetate (PMA) on protein kinase C (PKC) activity in human neutrophils. FMLP had little effect on the sharp decrease in cytosolic PKC activity induced by PMA. However, cells exposed to FMLP and PMA exhibited a synergistic increase in particulate PKC activity (1 +/- 1 pmol 32P/10(7) PMNs/min in unstimulated cells, 53 +/- 12 pmol 32P with 20 ng/ml PMA, 6 +/- 3 pmol 32P with 10(-7) M FMLP, and 191 +/- 17 pmol 32P with FMLP and PMA). FMLP also markedly increased calcium/phospholipid-independent protein kinase activity in particulate fractions of control and PMA-treated cells. Enhancement of PKC activity required the presence of cytochalasin B during cell stimulation. Cellular calcium was crucial to the FMLP effect since enhancement was decreased in cells incubated with EGTA or Quin2. These results suggest that chemotactic factors and phorbol esters may mediate synergistic effects on neutrophil responses through enhancement of particulate PKC activity. The enhancing effect is probably mediated through chemoattractant-mediated increases in intracellular calcium.

Enhancement of phorbol ester-induced protein kinase activity in human neutrophils by platelet-activating factor.

We have shown that platelet-activating factor (PAF), a weak primary stimulus for neutrophil superoxide generation, synergistically enhances neutrophil oxidative responses to the tumor promoter phorbol myristate acetate (PMA). Since PMA is known to cause cytosol-to-membrane shift of calcium-activated, phospholipid-dependent protein kinase (protein kinase c, PKC) in human neutrophils, we investigated the role of PAF in modifying PMA-induced PKC activation/translocation. Protein kinase activity was measured as the incorporation of 32P from gamma-32P-ATP into histone H1 induced by enzyme in cytosolic and particulate fractions from sonicated human neutrophils. PAF did not alter the sharp decrease in cytosolic PKC activity induced by PMA. However, in the presence of PAF and PMA, total particulate protein kinase activity increased markedly over that detected in the presence of PMA alone (144 +/- 9 pmoles 32P/10(7)PMN/minute in cells treated with 20 ng/ml PMA compared to 267 +/- 24 pmoles 32P in cells exposed to PMA and 10(-6)M PAF). The increase in total particulate protein kinase activity was synergistic for the two stimuli, required the presence of cytochalasin B during stimulation, and occurred at PAF concentrations of 10(-7) M and above. Both PKC and calcium-, phospholipid-independent protein kinase activities in whole particulate fractions were augmented by PAF as were both activities in detergent-extractable particulate subfractions. PAF did not directly activate PKC obtained from control or PMA-treated neutrophils. However, the PKC-enhancing effect of PAF was inhibited in the absence of calcium during cellular stimulation. PAF also increased particulate protein kinase activity in cells simultaneously exposed to FMLP but the effect was additive for these stimuli. These results suggest that PAF enhances PMA-induced particulate PKC activity by a calcium-dependent mechanism. The enhancing effect of PAF may be directly involved in the mechanism whereby the phospholipid "primes" neutrophils for augmented oxidative responses to PMA.

Platelet-activating factor induces protein kinase activity in the particulate fraction of human neutrophils.

Platelet-activating factor (PAF) is a proinflammatory lipid that has both platelet- and phagocyte-stimulating properties. Because several known activators of calcium-, phospholipid-dependent protein kinase (protein kinase c, PKC) also stimulate neutrophil responses and because neutrophil stimuli such as phorbol diesters and the chemotactic peptide f-Met-Leu-Phe are reported to increase protein kinase activity in neutrophil (PMN) particulate fractions, we investigated the effect of PAF on neutrophil protein kinase activities. In neutrophils exposed to 10(-6) mol/L PAF, cytosolic PKC activity was 521 +/- 38 pmol 32P/10(7) PMN/min (mean +/- SEM), which was not significantly lower than cystolic activity in buffer-treated controls (558 +/- 32 pmol 32P/10(7) PMN/min, n = 14). PAF-exposed cells exhibited a concomitant rise in protein kinase activity associated with the particulate fraction with 53 +/- 4 pmol 32P/10(7) PMN/min compared with 32 +/- 2 pmol in control cells (n = 14). Particulate protein kinase activity was independent of the presence of calcium and phospholipid in the assay medium. The specific PKC inhibitor H-7 inhibited particulate protein kinase activity, however, which suggested that the enzyme activity assayed in this fraction may be PKC in a constitutively activated form. The increase in particulate protein kinase activity induced by PAF required the presence of cytochalasin B, was detectable within 5 seconds of exposure to PAF, and was not reversed by washing the cells free of extracellular PAF after initial exposure. Although PAF did not have a direct effect on PKC activity from cytosolic fractions from resting cells, the increase in particulate protein kinase activity induced by PAF was inhibited when the cells were first depleted of calcium by incubation with Quin 2. These results suggest that PAF induces an increase in particulate protein kinase activity in neutrophils by a calcium-dependent mechanism and that the induction of membrane-associated protein kinase activity may be involved in neutrophil-stimulating actions such as superoxide production, which occur at higher concentrations of PAF.