Small volume coaxial discharge as precision testbed for 0D-models of XeCl lasers

In order to check the predictions of 0D-models experimentally, a small coaxial discharge configuration for the generation of homogeneous high pressure glow discharges (diameter 11 mm, length 20 mm) in rare gas halogen excimer laser gas mixtures under accurately controlled conditions has been developed. It uses X-ray preionization and a special pulse-forming network (PFN) delivering fast rising (8 ns) single square pulses (U ₀=25 kV; I=300 A; =100 ns). Discharge current and voltage are measured precisely by a capacitive voltage divider and a shunt integrated into the discharge chamber. All circuit data needed for the model calculations have been evaluated. Interferometric and spectroscopic diagnostics of the bulk of the discharge and of the cathode sheath have been performed. First results for Ne/Xe/HCl mixtures are compared with model calculations.     

Synthesis of exo-glycals and their biochemical applications

exo-Glycals are both valuable synthetic tools and biologically relevant structures. This article reviews the novel synthetic approaches that have been reported to synthesize sugar based tri- or tetrasubstituted exocyclic enol ethers. Among those, the Julia modified olefinations as well as the transition metal catalyzed cross-couplings have been extensively developed. The synthesis of unprecedented fluorinated and sulfonylated phosphono-exo-glycals are also described. An overview of the biological applications in which exo-glycals acts as inhibitors or inactivator of relevant enzymes is finally presented.     

Acid acting as redispersing agent to form stable colloids from photoactive crystalline aqueous sol–gel TiO<Subscript>2</Subscript> powder

In this work, the redispersion of three nanocrystalline TiO₂ colloids is studied: one pure and two Fe-doped titania. These three colloids are produced by an easy aqueous sol–gel synthesis using precipitation-acidic peptization of Ti precursor. For the two Fe-doped TiO₂, one is doped during synthesis (primary doping) and the other is doped after the synthesis (secondary doping). The initial colloids are composed of crystalline TiO₂ particles around 7?nm with good photocatalytic properties, tested on PNP degradation under visible light (wavelength >390?nm). The powders obtained by air drying of these three colloids are redispersed in water to produce colloids, which are compared to the initial colloid produced. For each colloid, five cycles of drying redispersion are achieved. The colloids are characterized by dynamic light scattering, zeta potential measurements, inductively coupled plasma–atomic emission spectroscopy, X-ray diffraction, nitrogen adsorption–desorption measurements, Mössbauer spectroscopy, diffuse reflectance spectroscopy, and photocatalytic tests. The results show that similar products are obtained between the cycles, maintaining homologous properties of colloids. This property of redispersion is mainly due to the acid (HNO₃, HCl, or H₂SO₄) which protonates the surface of the TiO₂ nanoparticle leading to high-surface charges and electrostatic repulsions between aggregates. This property can be very useful for industrial applications of this synthesis, especially as it allows the volume and weight to be reduced for transportation and storage. Moreover, results show that the pure TiO₂ powder can be doped during its redispersion step. The redispersion of the TiO₂ developed here is possible without surface functionalization or multiple step processes, contrary to commercial Degussa P25. A 2-year stability study of all the produced colloids has been performed by following the evolution of the macroscopic aspect and the physicochemical properties of these sols. This study showed high stability of the produced colloids.

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Selective Polymerization Catalysis from Monomer Mixtures: Using a Commercial Cr‐Salen Catalyst To Access ABA Block Polyesters

ABA triblock polyesters are synthesized using a commercially available chromium salen catalyst, in one pot, from monomer mixtures comprising epoxide, anhydride and lactone. The catalysis is highly selective and applies a single catalyst in two distinct pathways. It occurs first by epoxide/anhydride ring‐opening copolymerization and subsequently by lactone ring‐opening polymerization. It is used to produce various new ABA polyester polyols; these polyols can undergo post‐functionalization and chain‐extension reactions. The ability to use a commercial catalyst and switchable catalysis with monomer mixtures is expected to facilitate future explorations of new classes of block polymers.     

Phase separation in a three-dimensional,two-phase,hydrodynamic lattice gas

The dynamics of phase separation is explored using an immiscible 3D lattice-gas model. Scaling laws for the growth rate and power spectraS(k) of the growth patterns are computed. For small wavenumbersS(k) shows a crossover fromk ² tok ⁴ behavior. The theoretical prediction for the asymptotic domain growthRt ^2/3 is supported by our results. We discuss the possibility to observe an intermediatet scaling. We show the influence of hydrodynamic forces in symmetric and asymmetric mixtures by comparing simulations with and without momentum conservation. The structure functionS(k) is not significantly modified by hydrodynamics, but the growth rate changes clearly. As a general result, it is shown that, in spite of the unusual thermodynamics of this model, many characteristics of the growth dynamics are surprisingly in agreement with the classical theoretical and experimental results.