Microencapsulation technology for thiourea corrosion inhibitor

The microencapsulation technology was brought in to solidify corrosion inhibitor in order to prolong the releasing time of it. In this work, thiourea (H₂NCSNH₂) was used as a corrosion inhibitor and microcapsuled using glutin and polyvinyl alcohol (PVA), respectively, as protective agent. The re-sealing process was used as a way to prolong the releasing time of the H₂NCSNH₂ encapsulated in microcapsules. It was found that the H₂NCSNH₂ microcapsule corrosion inhibitor using PVA as a protective agent had a better releasing time. The releasing times of the H₂NCSNH₂ microcapsule corrosion inhibitors were prolonged from 18 to 48 h by re-sealing process and using PVA as a protective agent. Both the use of PVA as a protective agent and the application of the re-sealing process decreased the encapsulation efficiency of the H₂NCSNH₂. The performance parameters on protecting Q235 carbon steel from corrosion in 0.1-M H₂SO₄ solution were evaluated by polarization curve and electrochemical impedance spectra methods. The results showed that the H₂NCSNH₂ released into the solution from microcapsules could well protect Q235 carbon steel from corrosion and the corrosion-inhibiting mechanisms of it were the same as that of H₂NCSNH₂.     

Photochemical studies on η5-cyclopentadienyl(triphenylphosphine)nickelalkyl and -aryl compounds

Photo-induced degradation studies of a series of organonickel complexes of the type (η⁵-C₅H₅)(PPh₃)Ni(R) (R = CH₃, C₂H₅, C₆H₅ and C₆H₄CH₃-p) as well as certain deuterated analogs have been undertaken. Photolysis of the methyl compounds in benzene as well as benzene-d₆ gives methane as the major gaseous product, the photogenerated methyl group abstracting hydrogen from either the cyclopentadienyl ring, from the solvent, or from another methyl group. The photo-induced dealkylation of the ethyl compound gives both ethylene and ethane, and is explained by β-hydride elimination followed by subsequent reaction of the hydrido intermediate with additional ethyl compound. The photolysis of the phenyl and p-tolyl complexes in benzene solution leads to biaryl formation, both from the coupling of two coordinated aryl groups as well as interactions with the solvent. Triphenylphosphine is a product in all of these photo-decomposition studies.     

Enzymatic formation of unnatural novel polyketide scaffolds by plant-specific type III polyketide synthase

The catalytic potential of octaketide synthase (OKS), a plant-specific type III polyketide synthase (PKS) from Aloe arborescens, was investigated by phenylacetyl-CoA and benzoyl-CoA as starter substrates. As a result, a novel C₁₆ pentaketide coumarin was produced from phenylacetyl-CoA, whereas benzoyl-CoA was not a good substrate of OKS. Remarkably, a structure-guided OKS N222G mutant dramatically extended the product chain length to yield four novel polyketides including C₂₂ aromatic octaketides from the C₆-C₂ phenylacetyl starter, as well as a novel C₁₉ heptaketide benzophenone from the C₆-C₁ benzoyl starter.     

Über neue Sulfinyl- und Carbonyl-Pseudohalogen-Verbindungen

New Sulfinyl and Carbonyl Pseudohalogen Compounds FSO(NCO) ( 1 ) is formed as well during the attempt of synthesizing fluoroformyl sulfinylimide from OCFBr and Hg(NSO)₂ by an unexpected rearrangement as from OSFCl and Hg(NCO)₂ directly. FSO(NSOF₂) ( 2 ) was obtained analogously. Trying to get OS(NCO)₂, OC(NCO) (NSO) ( 3 ) was formed again by rearrangement as well as from ClCO(NCO) and Hg(NSO)₂.     

Study of the Effectiveness of Arsenic Hydride Generation from Various Arsenic Species with the Use of Some Borane Reducing Agents by Inductively Coupled Plasma Atomic Emission Spectrometry

Abstract

The application of H₃B–NH(CH₃)_2,H₃B–NH₂C(CH₃)₃ and NaBH₄ as derivatizing reagents in hydride generation from As(III), As(V), and As(V)-dimethyl forms was investigated. The effects of hydrochloric, acetic, and citric acids on the As responses were studied by using inductively coupled plasma optical emission spectrometry. Intensities of As, B, and H lines, and the pH of the reaction mixture were recorded. The effectiveness of the hydride generation depended on the arsenic form and changed with reductant type as well as with kind and concentration of the acids. The H line intensities were different from those expected from stechiometric reactions between the reductants and acids.     

Resolved single vibronic level fluorescence after two-photon excitation of benzene vapor: a direct confirmation of the inducing mode

Flourescence spectra have been observed from 1 and 5 torr of benzene after 504.2 nm excitation of the strongest two-photon band (linear polarization, ω₁ = ω₂) in the forbidden 260 nm ¹B_2u ← ¹A_1g absorption. The flourescence structure at 0.2 nm resolution is consistent with that expected from the fundamental ν′₁₄ in the excited state. This confirms directly the previous assignments of the dominant two-photon absorption progression as 1ⁿ_o14^L_o as well as the identity of the principal inducing mode, ν′₁₄ (b_2u). Vibrational relaxation from the level 14¹ appears similar to that observed from the one-photon levels.     

Studies on nessler's reagent and nessler's precipitate part II

The composition of the precipitate formed when the Nessler's reagent is treated with ammonia, is assumed as NH_n-1Hg₂I_n, aq. and has been studied potentiometrically from iodine-hypoiodite-system. It has been observed that the value of n depends on the concentrations of [HgI₄]^-2 and OH^- ions as well as on the amount of ammonia added and it may vary from 1 to 3. The colour of the precipitate deepens from brown to chocolate as the value of n increases.     

Crystallization mechanism and microstructure evolution of Li2O–Al2O3–SiO2 glass-ceramics with Ta2O5 as nucleating agent

Li₂O–Al₂O₃–SiO₂ glass-ceramics were prepared with Ta₂O₅ as nucleating agent, the crystallization mechanism and microstructure evolution were investigated by DTA, XRD, and SEM technologies. With increasing amount of Ta₂O₅ from 2 to 6 mol%, the crystallization activation energy decreased from 297.73 to 218.66 kJ mol^?1, while the crystallization index increased from 1.76 to 3.39. In addition, the cluster of dendritic crystals and lamellar structure obtained in T-2 glass-ceramics indicated a typical two-dimensional crystallization mechanism, and the formation of spherical β-quartz solid solution in T-4 specimens, with average size of 50–70 nm, was mainly due to bulk crystallization mechanism. It was considered that Ta₂O₅ promoted the nucleation and crystallization of LAS glass by precipitating the crystalline precursor phase of Ta₂O₅, which acted as nuclei for the subsequent crystal growth. Eventually, the diffusion and crystallization process, microstructure morphology, as well as the secondary grain growth were also investigated.     

Korrektur zur Kristallstruktur von „Cs4PbO3”︁ und die Strukturverwandtschaft zwischen den Modifikationen von Cs4PbO4

Correction of the Crystal Structure of “Cs₄PbO₃” and the Structural Relationship between the Modifications of Cs₄PbO₄ The compound that has been described as Cs₄PbO₃ really is Cs₄PbO₄. It does not crystallize in the space group P2₁, as assumed, but in P2₁/c. The observed fictitiuous violation of the extinction law for the c glide plane is due to twinning. The structure was refined using the original data as well as new data from an untwinned crystal. The denomination β-Cs₄PbO₄ is used to distinguish this structure from another known modification (α-Cs₄PbO₄). Both structures, α-Cs₄PbO₄ and β-Cs₄PbO₄, can be derived from the sphere packing of γ-plutonium when certain voids in its packing are occupied with oxygen atoms.     

Structures,raman, infrared and electronic absorption spectra of pyridinium trihalides

Vibrational and electronic absorption spectra of PyHI₃, PyHIBr₂, PyHICl₂, PyHBr₃ and PyHBrCl₂ are presented and explained in terms of the vibrations and electronic transitions, respectively, of the pyridinium and trihalide ions. Two compounds, PyHI₃ and PyHBr₃, show charge transfer bands in the absorption spectra of the solids, and the vibrational spectrum of the PyH⁺ ion in solid PyHBr₃ differs from the normal PyH⁺ spectrum. PyHBr₃ as well as PyHI₃ contains asymmetric trihalide ions in the solid state, as can be concluded from the Raman and infrared spectra.     

Electrochemical Formation of Fe(IV)=O Derived from H2O2 on a Hematite Electrode as an Active Catalytic Site for Selective Hydrocarbon Oxidation Reactions

The high-valence iron species (Fe(IV)=O) in the cytochrome P450 enzyme superfamily is generated via the activation of O₂, and serves as the active center of selective hydrocarbon oxidation reactions. Furthermore, P450 can employ an alternate route to produce Fe(IV)=O, even from H₂O₂ without O₂ activation. Meanwhile, Fe(IV)=O has recently been revealed to be the reactive intermediate during H₂O oxidation to O₂ on hematite electrodes. Herein, we demonstrated the generation of Fe(IV)=O on hematite electrodes during the electrochemical oxidative decomposition of H₂O₂ using in situ UV-visible absorption spectra. The generation of Fe(IV)=O on hematite electrodes from H₂O₂ exhibited 100 mV lower overpotential than that from H₂O. This is because H₂O₂ serves not only as the oxygen source of Fe(IV)=O, but also as the additional oxidant. Finally, we confirmed that the Fe(IV)=O generated on hematite electrodes can serve as the catalytic site for styrene epoxidation reactions.     

Formation of molecular hydrogen in photocatalytic systems containing heteropolytungstates as electron carriers

It has been shown that the heteropolytungstates [P₂W₁₈O₆₂]^6– and [SiW₁₂O₄₀]^40– act as the carriers in electron transfer from the conduction band of photoexcited CdS to Pd/SiO₂ in the reaction of producing H₂ from H₂O. The quantum efficiencies of these reactions have been determined, as well as the variation of the efficiency with changes in the quantitative composition of the photocatalytic system.Translated from Teoreticheskaya i Éksperimental'naya Khimiya, Vol. 30, No. 4, pp. 231–235, July–August, 1994.     

Studies on extraction behaviour of molybdenum (VI) from acidic radioactive waste using 2(ethylhexyl) phosphonic acids,mono 2(ethylhexyl) ester (PC-88A)/<Emphasis Type="Italic">n</Emphasis>-dodecane

This paper describes the studies on the extraction of molybdenum (VI) from aqueous nitric acid medium by (2-ethylhexyl) phosphonic acid, mono (2-ethylhexyl) ester (PC-88A). The extraction affecting parameters such as concentration of HNO₃ in aqueous feed, effect of concentration of extractants, effect of diluents, and molybdenum concentration in the aqueous phase are investigated to optimize the extraction conditions for the quantitative separation of molybdenum from nitric acid medium. With increase of HNO₃ concentration in aqueous phase, percentage extraction was found to be decreased in all the cases. Percentage extraction of molybdenum increases with increase in PC-88A concentration till the 0.15 M of PC88A, and after that it becomes constant. Kerosene and n-dodecane was found to be most suitable diluents. Among the various strippants used 0.2 M (w/v) solution of Na₂CO₃ and 0.2 M (w/v) solution (NH₄)₂CO₃ are found to be the equally suitable for stripping of molybdenum from the loaded organic phase. The stripping of molybdenum from loaded organic layer by various reagents followed the order: (NH₄)₂CO₃ >Na₂CO₃ >0.1 M sodium salt of EDTA >2 M NaOH >8 M HNO₃. The optimized process conditions are employed to extract molybdenum (VI) from actual Davies–Gray waste as well as from diluted high level waste generated in the purex stream. More than 94% Mo(VI) was extracted from radioanalytical as well as from high level waste of purex process and quantitative recovery was achieved in both the cases when 0.2 M sodium carbonate was used as stripping agent.     

Synthesis and Thermal Study of the Barium Complexes with 8-hydroxyquinolinate Derivatives

In this present work, barium ion was reacted with different ligands which are 5,7-dibromo 5,7-dichloro, 7-iodo and 5-chloro-7-iodo-8-hydroxyquinoline, in acetone/ammonium hydroxide medium under constant stirring and the obtained compounds were as follows: (I) Ba[(C₉ H₄ ONBr₂ )₂ ]⋅1.5H₂ O; (II) Ba[(C₉ H₄ ONCl₂ )(OH)]⋅1H₂ O; (III) Ba[(C₉ H₅ ONI)₂ ]⋅1H₂ O and (IV) Ba[(C₉ H₄ ONICl)₂ ]⋅5H₂ O, respectively. The compounds were characterized by elemental analysis, infrared absorption spectrum (IR), inductively coupled plasma spectrometry (ICP), simultaneous thermogravimetry-differential thermal analysis (TG-DTA) and differential scanning calorimeter (DSC). The final residue of the thermal decomposition was characterized as orthorhombic BaBr₂from (I); the intermediate residue, as a mixture of orthorhombic BaCO₃ and BaCl₂ and cubic BaO and the final residue, as a mixture of cubic and tetragonal BaO and orthorhombic BaCl₂ (II); the intermediate residue, as orthorhombic BaCO₃ and as a final residue, a mixture of cubic and tetragonal BaO from (III); and the intermediate residue, as a mixture of orthorhombic BaCO₃ and BaCl₂ and as a final residue, a mixture of cubic and tetragonal BaO and orthorhombic BaCl₂ from (IV). This revised version was published online in July 2006 with corrections to the Cover Date.     

Contribution of Discharge Excited Atomic N,N2*, and N2+ to a Plasma/Liquid Interfacial Reaction as Suggested by Quantitative Analysis

Electric-discharge nitrogen comprises three main types of excited nitrogen species-atomic nitrogen (N_atom), excited nitrogen molecules (N₂*), and nitrogen ions (N₂⁺) – which have different lifetimes and reactivities. In particular, the interfacial reaction locus between the discharged nitrogen and the water phase produces nitrogen compounds such as ammonia and nitrate ions (denoted as N-compounds generically); this is referred to as the plasma/liquid interfacial (P/L) reaction. The N_atom amount was analyzed quantitatively to clarify the contribution of N_atom to the P/L reaction. We focused on the quantitative relationship between N_atom and the produced N-compounds, and found that both N₂* and N₂⁺, which are active species other than N_atom, contributed to P/L reaction. The production of N-compounds from N₂* and N₂⁺ was enhanced upon UV irradiation of the water phase, but the production of N-compounds from N_atom did not increase by UV irradiation. These results revealed that the P/L reactions starting from N_atom and those starting from N₂^* and N₂⁺ follow different mechanisms.     

Diterpene Chemistry—VI : SeO2/H2O2 oxidations of exocyclic olefins

Unlike endocyclic olefins the major product from the SeO₂/H₂O₂ oxidation of exocyclic olefins is the same allylic alcohol as from the uncatalysed oxidation. Minor products derived from epoxide intermediates were investigated. The use of SeO₂ as an allylic oxidant for olefins has been extensively investigated, the functionality of the product being to a degree solvent dependent. Although the earlier mechanism of Guillemonat² is incorrect, his rules for the prediction of the position of oxidation still remain valid. A survey by Tratchenburg³ of the current position in SeO₂ oxidation postulates allylic oxidation as proceeding through the intermediacy of an oxaselenocyclobutane to a selenite ester which is solvated by competitive unimolecular (S_N1) and bimolecular (S_N2′) processes (Scheme 1).     

Synthesis and characterization of sol–gel derived glass-ceramic and its corrosion protection on 316L SS

Glass-ceramic was prepared by sol–gel method using Ca(NO₃)₂·4H₂O and P₂O₅ as Ca and P precursors, respectively. In order to improve the bioactivity of the implant material, glass-ceramic (β-Ca₂P₂O₇) coating was developed on 316L SS substrate by spin coating method. Coating was annealed at different temperatures and its corrosion resistance was evaluated by electrochemical polarization and impedance analysis using Ringer’s solution as electrolyte. The results from the present study, show excellent corrosion resistance for coated 316L SS, corroborated by the high values of charge transfer resistance from impedance analysis and higher breakdown and repassivation potential with the corresponding lower current density from polarization measurements. Based on the results, the glass-ceramic coating on 316L SS can be considered as a corrosion resistant material.     

Bakteriochlorophyll aGg und Bakteriophäophytin aP in den photosynthetischen Reaktionszentren von rhodospirillum rubrum G-9+

Bacteriochlorophyll a_Gg and Bacteriopheophytin a_p in Photosynthetic Reaction Centers from Rhodospirillum rubrum G-9⁺ In photosynthetically active reaction centers from Rhodospirillum rubrum G-9⁺, the magnesium complex bacteriochlorophyll a contains geranylgeraniol as the alcohol component, while the metal-free bacteriopheophytin a contains phytol instead. These pigments bacteriochlorophyll a_Gg ( 4 ) and bacteriopheophytin a_P ( 1 ) were isolated from reaction center preparations in a ratio of 2:1 and (after demetallation of 4 ) identified as bacteriopheophytin a_Gg ( 2 ), and a_P ( 1 ) by comparison with authentic samples (UV./VIS., CD. and mass spectra as well as mixed HPLC.).     

Electrochemically induced reversible solid state transformations: electrosynthesis of Ag2Cu2O4 by room temperature oxidation of Ag2Cu2O3

Electrochemical oxidation at room temperature of a slurry of Ag₂Cu₂O₃ yields a new silver copper oxide, formulated as Ag₂Cu₂O₄, with one more atom of oxygen per unit formula, that can in turn revert to the original precursor. The resulting oxide presents a different electronic and crystal structure from its precursor, as shown by XPS, X-ray and electron diffraction. This phase transformation involves a radical structural change from a 3D to a 2D network, as well as electronic changes involving silver and oxygen. The potential of electrochemical techniques to induce crystal-chemical solid state transformations is analyzed.     

Theoretical study on the one‐, two‐, and three‐photon absorption properties of exohedral functionalized derivative of Sc3N@C80

Geometrical structures of three investigated molecules Sc₃N@C₈₀, Sc₃N@C₈₀‐Fc, and C₆₀‐Fc were optimized by density functional theory (DFT) at the B3LYP/6‐31G* level. Then the time‐dependent DFT was employed to investigate the excited states of these molecules. After exohedral functionalization by ferrocene (Fc‐) group as the electron donor or replacing C₆₀ with Sc₃N@C₈₀ as the electron acceptor, the wavelengths of the first one‐photon absorption peak and the strongest two‐photon absorption (2PA) and three‐photon absorption (3PA) peaks shift red. The corresponding cross sections of Sc₃N@C₈₀‐Fc in the 2PA and 3PA processes increase as compared with those of Sc₃N@C₈₀, which originate from the contributions of charge transfers from Fc‐ group to C₈₀ cage and simultaneously the transfers from the C₈₀ cage to the encapsulated Sc₃N cluster. When compared with C₆₀‐Fc, the 2PA and 3PA cross sections of Sc₃N@C₈₀‐Fc decrease, which may result from the more negative charge surface of C₈₀ cage in Sc₃N@C₈₀‐Fc molecule which blocks the charge transfers from Fc‐ moiety to the C₈₀ cage in the excitation processes by compared with C₆₀‐Fc. © 2011 Wiley Periodicals, Inc. Int J Quantum Chem, 2012