Effect of Sodium Hydroarsenate on the Kinetics of Reduction of Hydrogen Ions at Iron and on the Hydrogen Diffusion through a Steel Membrane from Aqueous and Ethylene Glycol Solutions of Hydrochloric Acid

Effect of arsenic compounds H₃AsO₄, H₂AsO₄ ^–, and HAsO₄ ^2– on the hydrogen overvoltage, the slow stage of discharge of hydronium ions on the Armco iron, and the hydrogen diffusion through a steel membrane from aqueous and ethylene glycol solutions of hydrochloric acid with a constant ionic strength of unity is considered.     

Nickel complexes of N,N,N',N'′-tetrakis-(2- benzimidazolylmethyl)-1,2-diaminoethane (L) and the X-ray crystal structure of {[NiL]2+ [NiCl2(H2O)3(C2H5)OH)]}2Cl−(C2H5OH)

The preparation and properties of Ni(II) complexes of the title ligand (L) are described and the X-ray crystal structure of Ni₂LCl₄(H₂O)₃(C₂H₅OH)₂ is reported. The crystal structure shows that the two nickel ions are not bridged but exist as two distinct distorted octahedral species. Six coordination about one nickel ion is produced exclusively by L to give the cationic species [NiL]²⁺. The second nickel ion achieves six coordination through an interesting combination of ligands to produce the novel complex [NiCl₂(H₂O)3 (C₂H₅OH)]. Since the two remaining chloride ions are hydrogen bonded to two of the water molecules and the ethanol molecule of [NiCl₂(H₂O)₃(C₂H₅OH)] the entire complex can be considered to be formed by the cocrystallization of the large cation [NiL]²⁺ by the “large anion” {[NiCl₂(H₂O)₃(C₂H₅OH)]Cl₂}²⁻.     

Complexation in the CuCl2-C2H5OH-H2O system

Depending on the ethanol-water ratio, five individual compounds of copper(II) of the following compositions are formed in the CuCl₂-C₂H₅OH-H₂O system: [CuCl₂(C₂H₅OH)_4] (I), cis-[CuCl₂(C₂H₅OH)₂·(H₂O)₂] (II), trans-[CuCl₂(C₂H₅OH)₂· (H₂O)₂](III), [Cu(H₂O)₆]²⁺ (IV), and [Cu(OH)₂(H₂O)₄] (V).Translated from Izvestiya Akademii Nauk SSSR, Seriya Khimicheskaya, No. 12, pp. 2725–2729, December, 1990.     

Formation of Negative Hydrogen Ions in a Ne–H2 Hollow Cathode Discharge

The formation of negative hydrogen ions in a conventional hollow cathode discharge has been investigated. A mixture of Ne and H₂ proved to be more advantageous compared to pure hydrogen. The study has been performed by solving the electron Boltzmann equation, coupled with a system of balance equations for neon and hydrogen neutral and charged particles. The vibrational distribution function of hydrogen has been calculated. Our calculations show unusually high population of vibrationally excited hydrogen molecules in a Ne–H₂ mixture, which explains the high density of negative hydrogen ions under optimal conditions (total gas pressure of few Torr, hydrogen number mole fraction of 1–10% and discharge current of 10–100 mA). Line intensities originating from highly excited neon states vs. hydrogen pressure have been calculated and a comparison with existing experimental results has been made.     

Radiolysis in H2O/D2O mixtures. Hydrogen production under LOCA simulation

The hydrogen isotope radiolytic yields, G(H₂), G(HD) and G(D₂) were determined in H₂O/D₂O mixtures under chemical conditions close to a LOCA in a PHWR like Atucha I Nuclear Station, that is 2·10^–3 MH₃BO₃ and p(H+D)=8.5±0.2. The total hydrogen radiolytic yield G(H₂+HD+D₂) as a function of the deuterium atom fraction goes through a flat maximum at about 0.58. This result in dicates that the 4% flammability limit for hydrogen in the reactor's containment with be reached sooner than what is expected assuming a linear combination of pure H₂ and D₂ radiolytic yields. Hydrogen radiolytic production in 10^–3 M KBr in H₂O/D₂O mixtures gives the same results as in the boric solutions suggesting a bimolecular B(OH) ₄ ^– +OH reaction. Identical isotope concentration factors were calculated for both solutions.     

Mass spectrometry of macroheterocycles. 2. Characteristics of the fragmentation of azacrown ethers under electron impact

The fragmentation of aza-crown and diaza-crown ethers under electron impact was studied. It is shown that for the former the primary pathways of fragmentation of the molecular ions involve the intracyclic migration of a hydrogen atom and the elimination of C₂H₃O and CH₂OH particles. A characteristic feature of the diaza-crown ethers is the ejection of a divinylaminyl radical.For Communication 1 see [1].Translated from Khimiya Geterotsiklicheskikh Soedinenii, No. 2, pp. 242–246, February, 1992.     

Bis(ethylenedithio)tetrathiafulvalene bromide-ethylkne glycol: (BEDT-TTF)2Br·C2H4(OH)2. A new organic metal

A synthesis is reported for a new radical-cation salt (BEDT- TTF)₂Br·C₂H₄(OH)₂ having metallic electric conductance up to – 200 K. X-ray diffraction structural analysis was used to establish the existence of weak hydrogen bonds connecting the bromide ions with ethylene glycol molecules into infinite chains.Translated from Izvestiya Akademii Nauk SSSR, Seriya Khimicheskaya, No. 6, pp. 1438–1440, June, 1990.The authors thank R. B. Lyubovskii for measuring the electric conductance of a monocrystal of (I).     

Interaction of Aluminium (III) with the f-Family Ions Np(VI), Pu(VI), Np(V), Np(IV), Pu(IV), Nd(III), and Am(III) in the Course of Simultaneous Hydrolysis

The interaction of Np(VI), Pu(VI), Np(V), Np(IV), Pu(IV), Nd(III), and Am(III) with Al(III) in solutions at pH 0–4 was studied by the spectrophotometric method. It was shown that, in the range of pH 3–4, the hydrolyzed forms of neptunyl and plutonyl react with the hydrolyzed forms of aluminium. In the case of Pu(VI), the mixed hydroxoaqua complexes (H₂O)₃PuO₂(-OH)₂Al(OH)(H₂O)₃ ²⁺ or (H₂O)₄PuO₂OAl(OH)(H₂O)₄ ²⁺ are formed at the first stage of hydrolysis. Np(VI) also forms similar hydroxoaqua complexes with Al(III). The formation of the mixed hydroxoaqua complexes was also observed when Np(IV) or Pu(IV) was simultaneously hydrolyzed with Al(III) at pH 1.5–2.5. The Np(IV) complex with Al(III) has, most likely, the formula (H₂O) _n (OH)Np(-OH)₂Al(OH)(H₂O)₃ ³⁺. At pH from 2 to 4.1 (when aluminium hydroxide precipitates), the Np(V) or Nd(III) ions exist in solutions with or without Al(III) in similar forms. When pH is increased to 5–5.5, these ions are almost not captured by the aluminium hydroxide precipitate.     

Poly[aqua(μ3‐benzene‐1,2‐dicarboxylato)bis(μ3‐hydroxido)bis(μ2‐isonicotinato)dierbium(III) monohydrate] and the thulium analogue

The two isomorphous lanthanide coordination polymers, {[Ln₂(C₆H₄NO₂)₂(C₈H₄O₄)(OH)₂(H₂O)]·H₂O}_n (Ln = Er and Tm), contain two crystallographically independent Ln ions which are both eight‐coordinated by O atoms, but with quite different coordination environments. In both crystal structures, adjacent Ln atoms are bridged by μ₃‐OH groups and carboxylate groups of isonicotinate and benzene‐1,2‐dicarboxylate ligands, forming infinite chains in which the Er...Er and Tm...Tm distances are in the ranges 3.622 (3)–3.894 (4) and 3.599 (7)–3.873 (1) Å, respectively. Adjacent chains are further connected through hydrogen bonds and π–π interactions into a three‐dimensional supramolecular framework.     

Hydrogen bonding in the bromide salts of 4‐aminobenzoic acid and 4‐aminoacetophenone

In the title compounds, 4‐carboxyanilinium bromide, C₇H₈NO₂⁺·Br⁻, (I), and 4‐acetylanilinium bromide, C₈H₁₀NO⁺·Br⁻, (II), each asymmetric unit contains a discrete cation with a protonated amino group and a halide anion. Both crystal structures are characterized by two‐dimensional hydrogen‐bonded networks. The ions in (I) are connected via N—H...Br, N—H...O and O—H...Br hydrogen bonds, with three characteristic graph‐set motifs, viz. C(8), C₂¹(4) and R₃²(8). The centrosymmetric hydrogen‐bonded R²₂(8) dimer motif characteristic of carboxylic acids is absent. The ions in (II) are connected via N—H...Br and N—H...O hydrogen bonds, with two characteristic graph‐set motifs, viz. C(8) and R₄²(8). The significance of this study lies in its illustration of the differences between the supramolecular aggregations in two similar compounds. The presence of the methyl group in (II) at the site corresponding to the hydroxyl group in (I) results in a significantly different hydrogen‐bonding arrangement.     

Facile generation of platinum(IV) compounds with mixed labile moieties. Hydrogen peroxide oxidation of platinum(II) to platinum(IV) compounds

Hydrogen peroxide oxidation of platinum(II) compounds containing labile groups such as Cl, OH, and alkene moieties has been carried out and the products characterized. The reactions of [Pt^II (X)₂ (N–N)] (X = Cl, OH, X₂ = isopropylidenemalorate (ipm); N–N 2,2-dimethyl-1,3-propanediamine [(dmpda), N-isopropyl-1,3-propanediamine (ippda)] with hydrogen peroxide in an appropriate solvent at room temperature affords [Pt^IV (OH)(Y)(X)₂(N–N)] (Y = OH, OCH₃). The crystal structures of [Pt^IV(OH)(OCH₃)(Cl)₂(dmpda)]·2H₂O (P-1 bar, a = 6.339(2) Å , b = 9.861(1) Å, c = 11.561(1) Å, a = 92.078(9)°, β = 104.78(1)°, γ=100.54(1)°, V = 684.3(2) ų, Z = 2R = 0.0503) and [Pt^IV(OH)₂(ipm)(ippda)]·3H₂O (C 2/c, a = 27.275(6) Å, b=6.954(2) Å, c = 22.331(4) Å, β = 118.30(2)°, V = 3729(2) ų, Z = 8, R = 0.0345) have been solved and refined. The local geometry around the platinum(IV) atom approximates to a typical octahedral arrangement with two added groups (OH and OCH₃; OH and OH) in a transposition. The platinum(IV) compounds with potential labile moieties may be important intermediate species for further reactions.     

A System for Tracking Down Hydrogen Positions in Crystal Structures

Hydrogen conformations in [Ta₆Br₁₂(H₂O)₆]X₂ · trans — [Ta₆Br₁₂(OH)₄(H₂O)₂] · 18H₂O (X = Cl or Br), [Ta₆Br₁₂(H₂O)₆]₈ · (ZnBr₄)₈ · 96H₂O, Na₆[RuO₂{TeO₄(OH)₂}₂] · 16H₂O, and Na₅[Ag{TeO₄(OH)₂}₂] · 16H₂O were modeled from a set of simple rules. The systems are quite complex, but subsequent energy optimizations show that it is possible to make quite good predictions of where the hydrogen atoms are situated.     

Sb–C Bond Cleavage Reaction on a Triruthenium Cluster and the Formation of a Bridging Phenylacyl Unit

Syntheses and single crystal X-ray structures of an open triruthenium acyl carbonyl cluster [(C₆H₅)₂SbRu₃(COC₆H₅)(CO)₁₀] (1) and a simple triruthenium Ru₃(CO)₉[(C₆H₅)₂PCH₂P(C₆H₅)₂]Sb(C₆H₅)₃ (2) are reported. Formation of compound (1) at room temperature from [Ru₃(CO)₁₂] and [Sb(C₆H₅)₃] is unique, a similar reaction with Ru₃(CO)₁₀[(C₆H₅)₂PCH₂P(C₆H₅)₂] under identical conditions results in compound (2), with Sb(C₆H₅)₃ occupying an equatorial site. IR, ¹H, ¹³C NMR spectra of the compounds are reported. The X-ray crystal structure of (1) consist of 2 crystallography distinct molecules and shows Ru–Sb distances in the range: 2.6361(6)–2.6273(7) Å and Ru–Ru distances in the range: 2.8236(7)–2.9855(7) Å. Ru–O distances in the bridging carbonyl are: 2.137(4), 2.158(4) Å. The Sb–Ru–Ru angles in the two molecules of the asymmetric unit are in the range of 73.78(2)–77.52° indicating the puckered nature. Compound (2) has bond parameters comparable to those of Ru₃(CO)₁₀[(C₆H₅)₂PCH₂P(C₆H₅)₂]. The present study shows for the first time that the cleaving of Sb–C bond at room temperature is possible under non-ionic conditions, though there have been many instances of P–C and As–C bond cleavages reported previously.     

Studies on the series of azoles and azines. 65. Mass spectra of 5-arylidene-, 5-ethoxycarbonylmethylene-hydantoins and their derivatives

The mass spectra of 5-m- and p-substituted benzylidenehydantoins, their thio analogs and 5-carbethoxymethylenehydantoins with a substituent at the -carbon atom of the side chain were studied. The fragmentation of the molecular ions of 5-arylidenehydantoins proceeds in one direction, splitting of the X=C-NR-C=O fragment, irrespective of the substituent in the benzene ring. The peak intensity of the fragmentary ions formed from the molecular ions is linearly dependent on the -constants of the substituent. The direction of the fragmentation of 5-ethoxycarbonylmethylenehydantoins markedly depends on the substituent at the -carbon atom in the side chain that determines the stability of the hydantoin ring and the carboethoxyl group. The fragmentation of these compounds under electron impact proceeds by five paths, related to splitting of fragments O=C₍₂₎NCH₍₄₎=O, C₂H₄, C₂H₅O, C₂H₅OH, and COOC₂H₅.See [1] for Communication 64.Translated from Khimiya Geterotsiklicheskikh Soedinenii, No. 5, pp. 625–631, May, 1988.     

Kinetics and mechanism of the first aquation stage for the [Cr(pic)3]0 and [Cr(pic)2(OH)]2 0 complexes in HClO4 solutions

Aquation of [Cr(pic)₃]⁰ and [Cr(pic)₂(OH)]₂ ⁰ in aqueous HClO₄ solutions leads to formation of the common product – [Cr(pic)₂(H₂O)₂]⁺. The first, reversible stage, the ring opening via Cr—N bond breaking in [Cr(pic)₃]⁰ is followed by the second, rate-determining step – one-end bonded pic ligand liberation. In the case of the [Cr(pic)₂(OH)]₂ ⁰ complex, the first faster stage produces the singly bridged dimer, which undergoes cleavage into the parent monomers in the second, much slower step. The subsequent aquation of [Cr(pic)₂(H₂O)₂]⁺ is extremely slow and leads to [Cr(pic)(H₂O)₄]²⁺ formation, which practically does not undergo further ligand substitution under the conditions applied. Kinetics of the first aquation stage for [Cr(pic)₃]⁰ and of the second step for [Cr(pic)₂(OH)]₂ ⁰ were studied spectrophotometrically in the 0.1–1.0 M HClO₄ range at I = 1.0 M. The observed pseudo-first order rate constant for [Cr(pic)₃]⁰ decreases with [H⁺] increase according to the rate law: k _obs = k ₁ + k _–1 Q ₁/[H⁺], where k ₁ and k _–1 are the rate constants of the forward and the reverse processes in the unprotonated substrate and Q ₁ is the protonation constant of the pyridine nitrogen atom. In the case of the [Cr(pic)₂(OH)]₂ ⁰ complex, the rate for the singly bridged dimer cleavage does not depend on [H⁺]. The activation parameters for the chelate-ring opening in [Cr(pic)₃]⁰ and for the singly bridged dimer cleavage have been determined and discussed. Some kinetic data of the slow, second aquation stage for the [Cr(pic)₃]⁰ complex and of the fast, first aquation stage for the doubly bridged dimer have been studied; for both reactions the rate increases linearly with the increase in [H⁺].     

Carbon-13 kinetic isotope effects in the decarbonylation of lactic acid of natural isotopic composition in phosphoric acid medium

The¹³C kinetic isotope effect fractionation in the decarbonylation of lactic acid (LA) of natural isotopic composition by concentrated phosphpric acids (PA) and by 85% H₃PO₄ has been studied in the temperature interval of 60–150°C. The values of the¹³C₍₁₎ isotope effects in the decarbonylation of lactic acid in 100% H₃PO₄, in pyrophosphoric acid and in more concentrated phosphoric acids are intermediate between the values calculated assuming that the C₍₁₎–OH bond is broken in the rate-controllin gstep of dehydration and those calculated for rupture of the carbon-carbon bond in the transition state. In the temperature interval of 90–130°C the experimental¹³C fractionation factors determined in concentrated PA approach quite closely the¹³C fractionation corresponding to C₍₂₎–C₍₁₎ bond scission. the¹³C₍₁₎ kinetic isotope effects in the decarbonylation of LA in 85% orthophosphoric acid in the temperature range of 110–150°C coincide with the¹³C isotope effects calculated assuming that the frequency corresponding to the C₍₁₎–OH vibration is lost in the transition state of decarbonylation. A change of the mechanism of decarbonylation of LA in going from concentrated PA medium to 85% H₃PO₄ has been suggested. A possible secondary¹⁸O and a primary¹⁸O kinetic isotope effect in decarbonylation of lactic acid in phosphoric acids media have been discussed, too.     

Effect of Anodic Polarization on the Hydrogen Diffusion through a Steel Membrane in Ethylene Glycol Solutions

Diffusion of hydrogen through a steel membrane from ethylene glycol solutions of HCl containing 0.1–10 wt % H₂O is studied. The effect of the nature of discharging proton, hydrogen ion concentration, and anodic polarization on the process is considered. Kinetic parameters of cathodic reduction of proton donors on the Armco iron under similar experimental conditions are obtained.     

Dicopper(II) trihydroxide cyanoureate dihydrate

The title compound, poly[[μ‐cyanoureato‐tri‐μ‐hydroxido‐dicopper(II)] dihydrate], {[Cu₂(C₂H₂N₃O)(OH)₃]·2H₂O}_n, is a new layered copper(II) hydroxide salt (LHS) with cyanoureate ions and water molecules in the interlayer space. The three distinct copper(II) ions have distorted octahedral geometry: one Cu (symmetry ) is coordinated to six hydroxide groups (4OH + 2OH), whilst the other two Cu atoms (symmetries and 1) are coordinated to four hydroxides and two N atoms from nitrile groups of the cyanoureate ions (4OH + 2N). The structure is held together by hydrogen‐bonding interactions between the terminal –NH₂ groups and the central cyanamide N atoms of organic anions associated with neighbouring layers.     

Sugar‐Alcohol Complexes of Palladium(II): On the Variable Rigidity of Open‐Chain Carbohydrate Ligands

The C₄, C₅, and C₆ sugar alcohols erythritol (Eryt), D ‐threitol (D ‐Thre), D ‐arabitol (D ‐Arab), ribitol (Ribt), xylitol (Xylt), dulcitol (Dulc), and D ‐mannitol (D ‐Mann) form chelate complexes upon dissolution in Pd‐en, an aqueous solution of [Pd^II(en)(OH)₂]. Stability rules are derived from the proportion of a respective species in the solution equilibrium. Crystal‐structure analysis supports the NMR spectroscopic results for a series of binuclear compounds that contain the sugar alcohols as tetraanionic polyolato ligands: [Pd₂(en)₂(ErytH_?4)]? 10H₂O, [Pd₂(en)₂(D ‐Arab1,2;3,4H_?4)]? 7H₂O, [Pd₂(en)₂(Xylt1,2;3,4H_?4)]?4H₂O, [Pd₂(en)₂(D ‐Mann1,2;3,4H_?4)]?5H₂O, and [Pd₂(en)₂(Dulc2,3;4,5H_?4)]?6H₂O. In the case of the pentitols and hexitols, the metalated tetraanions are stabilized by intramolecular hydrogen bonds. The hydrogen bonds uniformly connect an alkoxide acceptor to the hydroxy donor group located at the δ carbon atom. As a consequence of hydrogen bonding, the open‐chain carbohydrate ligands become rigid. Crystal‐structure analysis provides information on the configurational requirements for rigidity. According to these rules, the hydrogen‐bond‐supported Dulc2,3;4,5H_?4 tetraanion provides a geometrically persistent ligating pattern. Intramolecular hydrogen bonding seems to be the most‐competitive variable to metalation of a polyol. [Pd₂(tm‐2,1:3,2‐tet)(OH)₃]OH (tm‐2,1:3,2‐tet=1,3‐bis(2′‐dimethylaminoethyl)hexahydropyrimidine) is a metallizing agent that can force full metalation even in a case as intractable as that of dulcitol. Accordingly, [Pd₄(tm‐2,1:3,2‐tet)₂‐(DulcH_?6)]Cl₂?16H₂O contains the fully deprotonated hexitol as the ligand.     

Dinuclear copper(<Emphasis Type="SmallCaps">II</Emphasis>) complexes with an unsymmetrical exchange fragment

New dinuclear copper(II) complexes with azomethines and hydrazones, which were produced by condensation of substituted salicylaldehyde derivatives with 1,3-diaminopropan-2-ol or carbo(thiocarbo) hydrazide, were studied. The structures of the [Cu₂L(μ-CH₂ClCOO)(CH₃OH)]·(CH₃OH) (L = C₁₇H₁₅N₂O₃) and [Cu₂L²(Cl₃CCO)(CH₃OH)]·H₂O (L² = C₃₂H₄₂N₄O₃) complexes were established by X-ray diffraction. The magnetic properties of these complexes, including the influence of the nature of the substituents in the ligands on exchange interactions, were studied.__________Published in Russian in Izvestiya Akademii Nauk. Seriya Khimicheskaya, No. 3, pp. 592–596, March, 2005.