Kinetics and mechanism of base hydrolysis of Reinecke's salt revisited – specific salt effects

The kinetics of base hydrolysis of the trans-[Cr(NH₃)₂(NCS)₄]^– anion follows the rate law: -d[complex]/dt = k ₀ + k ₁[OH^–] (50–70 °C, [OH^–] = 0.1–1.9 M and = 2.0 M). The specific salt effect has been investigated for eight aqueous media: NaCl, NaBr, NaI, NaClO₄, KCl, KBr, CsCl and CsBr. The alkali-independent path (k ₀) does not show any specific effect of inert electrolyte ions, the activation parameters: H = 113.5 ± 0.4 kJ mol^–1 and S = 24.1 ± 1.3 J mol^–1 K^–1 are interpreted in the frame of a dissociative interchange mechanism (I _d). For the alkali-dependent path (k ₁) the specific salt effect is observed for cations of the inert electrolyte, showing an important role for ion-pair formation between the cations and reagent complex anion in the activation process. A linear correlation between lnk ₁ and lnK ₀ (K ₀ – ion-pair formation constant) has been found for the cations studied. The dissociative, via conjugate base, mechanism (D _CB) has been proposed for the alkali-dependent path.     

The crystal structure of Fe(SeO2OH)(SeO4)·H2O

Summary The crystal structure of the hydrothermally synthesized compound Fe(SeO₂OH) (SeO₄) · H₂O was determined by single crystal diffraction methods:a=8.355(2) Å,b=8.696(2) Å,c=9.255(2) Å, =93.72(1)°,V=670.95 ų;Z=4, space group P2₁/c,R=0.029,R _w=0.027 for 2430 independent reflections (sin /0.76 Å^–1). Isolated FeO₅(H₂O)-octahedra share five corners with [SeO₂OH] and [SeO₄] groups to form sheets parallel to (100). These sheets are interconnected via hydrogen bonds only.

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Die Kristallstruktur von Fe(SeO₂OH)(SeO₄)·H₂O

Zusammenfassung Die Kristallstruktur der hydrothermal dargestellten Verbindung Fe(SeO₂OH) (SeO₄)·H₂O wurde mittels Einkristallbeugungsmethoden bestimmt:a=8.355(2) Å,b=8.696(2) Å,c=9.255(2) Å, =93.72(1)°,V=670.95 ų;Z=4, Raumgruppe P2₁/c,R=0.029,R _w=0.027 für 2 430 unabhängige Reflexe (sin / 0.76 Å^–1). Isolierte FeO₅(H₂O)-Oktaeder teilen fünf Ecken mit [SeO₂OH]- und [SeO₄]-Gruppen, wobei sie Schichten parallel (100) bilden. Diese Schichten sind nur über Wasserstoffbrücken miteinander verbunden.

     

Formation and reactions of metal-metal bonded heterobimetallic (C5H4PR2)-bridged (Zr-Ir) and (Zr-Rh) complexes: evidence for the participation of metal hydride intermediates

Treatment of the complexes [(C(5)H(4)PR(2))(2)Zr(CH(3))(2)](b: R = isopropyl; c: R = cyclohexyl) with the reagent HIr(CO)(PPh(3))(3) (2b) yield the heterobimetallic complexes [mu-C(5)H(4)PR(2))(2)(H(3)C-Zr-Ir(CO)(PPh(3)))] (4b, 4c) with evolution of methane. The reaction of the -PPh(2) substituted analogue with initially yields an intermediate [(H(3)C)(2)Zr(mu-C(5)H(4)PPh(2))(2)Ir(H)(CO)(PPh(3))] 5a, that still contains both methyl groups at zirconium and does not contain a metal-metal bond. At room temperature, the intermediate reacts further with methane formation to eventually yield the (Zr-Ir) complex 4a. The corresponding [mu-C(5)H(4)PR(2))(2)(H(3)C-Zr-Rh(CO)(PPh(3)))] complexes 3a (R = Ph) and 3b (R = isopropyl) react cleanly with isopropyl alcohol to liberate methane and yield the corresponding [mu-C(5)H(4)PR(2))(2)(Me(2)CHO-Zr-Rh(CO)(PPh(3)))] products (7a, 7b). Carefully monitoring the reaction of with Me(2)CHOH by NMR revealed that the Zr-Rh functionality is attacked first to give the intermediate [Me(Me(2)CHO)Zr([micro sign]-C(5)H(4)PR(2))(2)Rh(H)(CO)(PPh(3))] (6b). This intermediate then reacts further to cleave off methane and re-form the (Zr-Rh) metal-metal bond to yield the product 7b. The tetrametallic mu-oxo-(Zr-Rh) metallocene derivate 11a was obtained starting from the (Zr-Rh) complex 3a and it was characterized by X-ray diffraction. It may be that this reaction is also initiated by H-OH addition to the [Zr-Rh] metal-metal bond.     

Zur Kenntnis der anomalen Reaktionen bei der Aminostickstoffbestimmung. VI Die Anomalie des Indols und seiner Derivate

Zusammenfassung Es wurde untersucht, warum Indol und viele seiner Derivate bei der Aminostickstoffbestimmung ein Gasvolumen liefern, obwohl sie keine primäre Aminogruppe besitzen. An Hand von präparativen Befunden wird gezeigt, daß die anomale Reaktion bei Indol in folgender Weise abläuft: Bei Einwirkung von salpetriger Säure bildet sich 3-Nitrosoindol, das sieh mit freiem Indol zu Indolrot polymerisiert. Gleichzeitig lagert sich die Nitrosogruppe zur Isonitrosogruppe um. Diese reagiert nun mit überschüssiger salpetriger Säure unter Entwicklung von Stickstoff und Distickstoffoxyd. Ist die Stellung 2 und 3 besetzt, so bleibt die anomale Gasentwicklung aus, da sich keine Isonitrosoverbindung bilden kann. Es wurde auch das Verhalten von 3-Methylindol und 3-Indolylessigsäure untersucht und die anomale Reaktion erörtert.

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Summary A study was made to learn why indole and many of its derivatives deliver a gas volume during the determination of the amino nitrogen, even though they contain no primary amino group. On the basis of preparative findings, it was shown that in the case of indole the anomalous reaction proceeds in the following fashion. When the nitrous acid reacts, 3-nitrosoindole is formed, which then polymerizes with free indole to indole red. At the same time, the nitroso group rearranges into the isonitroso group. The latter reacts with excess nitrous acid with evolution of nitric oxide and nitrogen dioxide. If positions 2 and 3 are occupied, there is no anomalous generation of gas, because no isonitroso compound can form. The behavior of 3-methylindole and 3-indylacetic acid was also studied and the anomalous reaction noted.

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Résumé Les auteurs ont recherché pourquoi l'indol et nombre de ses dérivés donnent lieu à un dégagement gazeux lors de la détermination de l'azote aminé bien qu'ils ne contiennent aucun groupement aminé primaire. Des constatations effectuées au cours de travaux de chimie préparative ont montré que la réaction anormale de l'indol a le cours suivant: lors de l'action de l'acide nitreux il se forme du nitroso-3 indol qui en présence d'indol libre se polymerise en rouge d'indol. Simultanément le groupement nitrosé se transpose en groupement isonitrosé. Ce dernier réagit alors avec l'acide nitreux en excès en donnant lieu à un dégagement d'azote et de protoxyde d'azote. Si les positions 2 et 3 sont occupées il ne se produit pas de dégagement gazeux anormal car la combinaison isonitrosée ne peut se former. Les auteurs ont également examiné le comportement du méthyl-3 indol et de l'acide indoyl-3 acétique et discuté leurs réactions anormales.

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I: Anomalie der Isonitrosoverbindungen¹; II: Anomalie der Verbindungen mit NH-CO-Gruppierung²; III: Anomalie der Verbindungen mit aktiven Methylengruppen³; IV: Anomalie von Glycin⁴; V: Anomalie der Phenole⁵.     

CHEMILUMINESCENCE IN THE PEROXIDATION OF TANNIC ACID

Abstract— Peroxidation of tannins with alkaline H₂O₂ is accompanied by weak chemiluminescence in the spectral region 480–800 nm. o-Di and tri-hydroxy groups of polyphenols undergo oxidation by a free-radical mechanism and a green intermediate anion-radical with absorption Δ_max= 600 nm is formed. The radical mechanism is supported by the low activation energy 14–20 kJ/mol and the quenching effect of radical scavengers. The reaction of the green intermediate with peroxy anions is the chemiluminescence rate limiting step. In the presence of a-hydroxy-methylperoxide formed from H₂O₂ and formaldehyde, the alkaline peroxidation of tannins is accompanied by strong red luminescence (420–800 nm). The base catalyzed decomposition of peroxides gives only a weak red emission (460–800 nm). Light intensity is enhanced in D₂O by a factor 6.5. Quenchers of O₂(¹Δ_g) and 1,3-di-phenylisobenzofurane diminish light intensity in non-aqueous solutions. The data suggest ¹O₂ participation in the observed chemiluminescence. Thermo-chemical calculations give —ΔH values from 250–1000 kJ/mol for one elementary reaction step which limits the mechanism of chemi-enereization. Chemiexcitation of tannins is relevant to biochemical mechanisms of aerobic degradation of aromatic compounds, energy utilization as well as to defense and resistance processes in plants.     

Determination and characterization of a transition structure for water–formaldehyde addition

Quantum mechanical calculations of the geometric, energetic, electronic, and vibrational features of a transition structure for gas-phase water–formaldehyde addition (FW1?) are described, and a new transition-structure search algorithm is presented. Basis-set-dependent effects are assessed by comparisons of computed properties obtained from self-consistent field (SCF) molecular orbital (MO) calculations with STO-3G, 4-31G, and 6-31G^** basis sets in the absence of electron correlation. The results obtained suggest that STO-3G-level calculations may be sufficiently reliable for the prediction of the transition structure of FW1? and for the transition structures of related carbonyl addition reactions. Moreover, the calculated activation energy for formation of FW1? from water and formaldehyde (?44 kcal mol^?1) is very similar in all three basis sets. However, the energy of formaldehyde hydration predicted by STO-3G (? ?45 kcal mol^?1) is about three times larger than that predicted by the other two basis sets, with the activation energy for dihydroxymethane dehydration also being too large in STO-3G. Calculated force constants in all three basis sets are generally too large, leading to vibrational frequencies that are also too large. However, uniformly scaled force constants (in internal coordinates) give much better agreement with experimental frequencies, scaled 4-31G force constants being slightly superior to scaled STO-3G force constants.     

Conjugated schiff's bases.20 cycloaddition of heterocomulenes to some 1,3-heterodienes involving unusual assistance of methyl group

Highly substituted 1,Δ-diazabutadienes react with aroyl isothiocyanates in a 1,3-dipolar cycloaddition node yielding five-membered thiohydantoin-type heterocycles. The cycloaddition is accompanied by 1,4 shift of hydrogen from a methyl group attached to C2 of the 1,C-diazabutadiene moiety. The mechanism of this reaction is discussed in comparison with similar cycloadditions with aryl isocyanates.     

Kinetics and mechanism of one dipicolinato ligand substitution in the chromium(III)–bis(dipicolinato) complex: an unusual rate dependence on acid concentration

The Na[Cr(PDA)₂] · 2H₂O complex (PDA¹ = dipicolinic acid anion) and its aquation product, [Cr(PDA)(H₂O)₃]⁺, were prepared and characterized. The electronic spectra demonstrate that the bis(dipicolinato) complex undergoes very fast partial dechelation during dissolution. In acidic media, pH controlled, rapid protolytic and ring opening processes lead to coexistence of complexes with one tridentate (PDA) and the other bi- or mono-dentate (PDA). The kinetics of PDA ligand liberation were followed spectrophotometrically within the 0.1–2.0 M HClO₄ range at I = 2.0 M. The observed first-order rate constant depends on [H⁺] according to the equation: k _obs = A[H⁺]/(1 + B[H⁺] + C[H⁺]²). A reaction course via the uncharged [Cr(PDA)(HPDA)(H₂O)₂]⁰ complex is proposed. The observed rate increase, followed by rate retardation with [H⁺] increase, is attributed to the unreactive [Cr(PDA)(H₂PDA)(H₂O)₂]⁺ complex. In terms of the proposed mechanism, A, B, C parameters have been defined as: A = k ₁ Q ₁, B = Q ₁, C = Q ₁ Q ₂ where k ₁ is the rate constant of the Cr^III-carboxylato oxygen bond-breaking in the monodentate HPDA ligand, Q ₁ is a composite value describing protolytic and dechelation processes and Q ₂ is the protonation constant of the uncharged [Cr(PDA)(HPDA)(H₂O)₂]⁰ complex.