Determination of the Enthalpies of Vaporization of Cyclic Organic Peroxides by Correlation of Changes in Gas Chromatographic Retention Times

Liquid and solid cyclic peroxides derived from aliphatic ketones are explosive materials so their enthalpies of vaporization and other thermodynamic or condensed-phase properties cannot be measured directly. In this work the enthalpies of vaporization of peroxides at 298.15 K were estimated simply from gas chromatographic retention times measured at different temperatures. The technique correlates changes in the retention times of compounds whose enthalpies of vaporization are known (called the reference series), with those of the compounds of interest. If t _R′ is the adjusted retention time (retention time of each compound minus the retention time of unretained diethyl ether, used as solvent) a plot of ln t _R′ against 1/T for each compound (reference compounds and cyclic peroxides) results in a straight line (r ² > 0.99 for all compounds). The enthalpy of transfer from solution to the vapor state (Δ_sol^g H _m) can be obtained by multiplying the slope by the gas constant (R). A second plot correlates the enthalpies of transfer from solution to the vapor state (Δ_sol^g H _m), as measured by gas–liquid chromatography (GLC), with enthalpies of vaporization of reference materials (Δ_vap H _m at 298.15 K) available in the literature. C₉–C₁₅ fatty acid methyl esters and hydrocarbons were used as reference compounds. The enthalpies of vaporization of the cyclic organic peroxides were calculated from the equation of the line obtained in this second correlation, the slope of which was Δ_vap H _m (at 298.15 K)/Δ^g _sol H _m. The experiments were performed under isothermal conditions with a DB-5 capillary column, flame-ionization detection (FID), and nitrogen as carrier gas. The column temperature was varied over a range of at least 30–70 K between 403 and 473 K, with chromatograms being acquired at 10 K intervals. Enthalpies of vaporization of cyclic organic peroxides are not available in the literature, and the values given in this paper, obtained by gas chromatography, are the first to be reported.     

The free-radical reaction of tri-n-butyltin hydride with peroxides

Rate constants for the tri-n-butyltin radical ( Sn · ) induced decomposition of a number of peroxides have been measured in benzene at 10°C. The values range from ～100 M^?1 sec^?1 for di-t-butyl peroxide to 2.6 × 10⁷ M^?1 sec^?1 for di-t-butyl diperoxyisophthalate. The majority of the peroxides, including diethyl peroxide, diacetyl peroxide, and t-butyl peracetate, have rate constants of ～10⁵ M^?1 sec^?1. It is shown that di-n-alkyl disulfides are ten times as reactive toward Sn · as di-n-alkyl peroxides, although the exothermicities of these reactions are ～15 and ～39 kcal/mole, respectively. The enhanced reactivity of the disulfides is attributed to the easier formation of an intermediate or transition state with 9 electrons around sulfur, compared with an analogous species with 9 electrons around oxygen. The following bond strengths (kcal/mole) have been estimated: D[ Sn ? OR] = 77; D[ Sn ? H] = 82; D[ Sn ? SR] = 83; and D[ Sn ? OC(O)R] = 86, where R = alkyl. Rate constants for reaction of Sn · with some benzyl esters have also been measured. It has been found that t-butoxy radicals can add to benzene and abstract hydrogen from benzene at ambient temperatures.     

Amavadin,an Example for Selective Binding of Vanadium in Nature: Studies of Its Complexation Chemistry and a New Structural Proposal

The selective enrichment of metals in nature is of great interest.^[1] For example, the concentration of vanadium in the blood of tunicates is a millionfold higher than in sea water.^[2–4] Fly agaric (Amanita muscaria) also concentrates vanadium.^[5,6]The structure of the vanadium compound of tunicates has not yet been elucidated.^[7,8] However, a structure ( 3 ) has been proposed^[9] for the vanadium compound of fly agaric, amavadin.^[9-11] The structural elucidation and synthesis of the organic ligand 1b ^[9b] allows, for the first time, the specificity of a naturally occurring vanadium ligand to be investigated. Amavadin can be prepared from V^IVO salts and synthetic 1b .^[9b] Since the ligand 1b was previously unknown and since all attempts to obtain crystals of amavadin suitable for an X-ray structure analysis failed, a detailed investigation of the complex formation of 1b should also provide an answer to the question of the arrangement of the ligands around the central atom in amavadin.     

Synthesis of Long,Palladium End‐Capped Polyynes through the Use of Asymmetric 1‐Iodopolyynes

The synthesis of a unique series of long, asymmetric 1‐iodopolyynes ( 1 ‐C_nI and 2 ‐C_nI) with the sp‐hybridized carbon chain up to a decapentayne is reported. These compounds were then used as substrates in reactions with Pd(PPh₃)₄ leading to another series of palladium end‐capped polyynes, which were unstable in solution. Organometallic octatetraynes 1 ‐C₈[Pd]I, 2 ‐C₈[Pd]I, and decapentayne 1 ‐C₁₀[Pd]I are palladium end‐capped polyyne compounds with the longest carbon chains reported so far. All the complexes as well as their organic precursors were fully characterized by NMR, HRMS(ESI), IR, TGA‐DTA, and UV/Vis techniques, and the X‐ray crystal structures of two silyl‐protected precursors and one palladium complex are presented. The synthetic approach for palladium species is envisioned as a general route for the synthesis of labile organometallic polyynes.     

Air‐Stable,Well‐Soluble AI2[Nb6Cl18] Cluster Compounds (AI = Organic Cation): A New Route for Preparation,Single‐Crystal Structures,Properties, and ESI‐Mass Spectra

Five niobium cluster compounds of the A^I₂[Nb₆Cl₁₈] type (A^I = organic cation: [nPr₄N]⁺, [nBu₄N]⁺, [BMIm]⁺, [Ph₄P]⁺, and [PPN]⁺) are obtained through treatment of [Nb₆Cl₁₄(H₂O)₄] · 4H₂O with excess of thionyl chloride in the presence of an organic chloride, A^ICl. Single‐crystal structure studies show that the compounds consist of discrete cations and cluster [Nb₆Cl₁₈]^2– anions. The cluster unit of the hydrated cluster starting material is oxidized by two electrons. Powder diffraction studies and NMR spectroscopic measurements show all compounds to crystallize without co‐crystallized solvent molecules. They are air and water stable. The solubility in organic solvents changes to a great extent on changing the type of cation. The ESI‐MS spectra of [nPr₄N]₂[Nb₆Cl₁₈] and [Ph₄P]₂[Nb₆Cl₁₈] show the pseudomolecular peak of the anionic cluster as well as additional signals, which involve simultaneously chloride mass loss and reduction processes.     

Recent Progress in Oxo- and Fluorometalate Chemistry

About a quarter of a century ago a review article having almost the same title appeared in this journal^[1]. Since then many hundreds of new fluorides and oxides of metals have been synthesized, and repeatedly subjected to detailed investigation. Why, and to what end are such compounds still studied^[2]? Has our knowledge been not only widened but also deepened? What advances have been made in synthetic chemistry in this sector? Have new ideas led to unforeseen results and have unexpected findings forced the revision of tested concepts? This area of research belongs to solid state chemistry, and in the meantime has become almost unsurveyable even for a committed researcher. In this paper, therefore, an attempt is made to outline any relevant advances that have been made and to present open questions and new aspects using selected examples, mainly from the chemistry of the first row of the transition metal series. Those not directly involved in this area may be surprised to find that even substances with a simple composition are also cited. They might ask whether such compounds mentioned in text books are not already understood. Although it is a widely-held view that such compounds are well known, this is incorrect: Probably no-one has ever prepared a sample of CrF₂ or Na₂O whose composition “adequately” exactly corresponded to the quoted formula^[3]. Typical examples which demonstrate the considerable effort necessary for finally proving what others long ago already assumed to know, can be taken from the area of inorganic chemistry (e.g.: As₂O) as well as from organic chemistry (e.g. C₄[C(CH₃)₃]).     

Synthesis,Characterization, and Physicochemical Properties of Hydrophobic Pyridinium‐based Ionic Liquids with N‐Propyl and N‐Isopropyl

Synthesis and physicochemical properties of four pyridinium‐based ionic liquids (ILs), N‐propylpyridinium bromide [N‐propylPyr]⁺[Br]^–, N‐isopropylpyridinium bromide [N‐isopropylPyr]⁺[Br]^–, N‐propylpyridinium hexafluorophosphate [N‐propylPyr]⁺[PF₆]^–, and N‐isopropylpyridinium hexafluorophosphate [N‐isopropylPyr]⁺[PF₆]^– are reported. The molecular structures of these compounds were characterized by FT‐IR, ¹H, ¹⁹F, and ³¹P NMR, spectroscopy. The thermal properties, conductivity, and solubility of these ionic liquids were also investigated. The effects of propyl and isopropyl alkyl lateral chain at the N‐position of pyridinium cation on the thermal stability, conductivity, and solubility of ionic liquids are discussed. The results obtained confirmed that the ionic liquids based on pyridinium cations exhibit higher decomposition temperature, low melting points, immiscible with water, and their conductivities are mainly influenced by mobility of ions.     

Unusual open chain quinolinyl peroxol and its alcohol counterpart obtained through a modified Skraup–Doebner–Von Miller quinoline synthesis: theoretical studies and complete 1H‐ and 13C‐NMR assignments

Because of their extreme instability, it is generally difficult to synthesize and fully characterize open chain peroxides, also known as peroxols. In our attempt to investigate the mechanism of the Skraup–Doebner–Von Miller quinoline synthesis, we were able to obtain an unusual open chain peroxy‐quinoline, namely, 4‐(8‐ethoxy‐2,3‐dihydro‐1H‐cyclopenta[c]quinolin‐4‐yl)butane‐1‐peroxol (1), and its alcohol counterpart, namely 4‐(8‐ethoxy‐2,3‐dihydro‐1H‐cyclopenta[c]quinolin‐4‐yl)butan‐1‐ol (2) obtained as a side product during the same reaction. Although structurally similar, these two compounds appeared to display some very distinct physical and spectroscopic characteristics. This work reports detailed NMR studies and full ¹H and ¹³ C NMR assignments for these two compounds. These assignments are based upon the analysis of the NMR spectra of these compounds including ¹H, ¹³ C, COSY, gHSQC and gHMBC. The effect of the peroxide functional group on the chemical shift of neighboring carbons and protons was also investigated by comparing the NMR data of these two compounds. Furthermore, the effects of potential hydrogen bondings in 1, 2, and possible 1–1 dimer, 2–2 dimer and in prototypical model systems, as well as the stability of these compounds, were investigated computationally. The computed dissociation energies and NMR data support the interpretation of the experimental data. Copyright © 2012 John Wiley & Sons, Ltd.     

Hexanuclear Niobium Cluster Complex Anions with Acetato Ligands on Intramolecular Bridging Sites: [Nb6Cli4(OAc)i8Cla6]2– and [Nb6(OAc)i12Cla6]2–

From the reaction of [Nb₆Cl₁₄(H₂O)₄] · 4H₂O with acetic anhydride in the presence of an excess of (nBu₄N)F the novel cluster compounds (nBu₄N)₂[Nb₆Clⁱ₄(OAc)ⁱ₈Cl^a₆] ( 1 ) and (nBu₄N)₂[Nb₆(OAc)ⁱ₁₂Cl^a₆] ( 2 ) (OAc = acetato ligand) are obtained. They are the first examples of hexanuclear niobium cluster compounds with acetato ligands on the inner sites of the metal atom octahedron. The crucial role of the presence of fluoride ions in the synthesis is discussed. Each acetato ligand bridges in a μ₂-η¹-fashion with one O atom an edge of the metal atom octahedron. The monoclinic crystals of 1 consist of discrete (nBu₄N)⁺ cations and [Nb₆Clⁱ₄(OAc)ⁱ₈Cl^a₆]^2– cluster anions. They are oxidized by two electrons with respect to the cluster starting material. Besides the syntheses of 1 and 2 , the structure of 1 and spectral properties of both compounds are reported.     

用扩展的Istomin-Palm模型估算双向延伸化合物R1-Y-R2生成焓

Istomin和Palm曾提出用模型Δ_fH⁰(RX)=h[R]+h[X]+φ[R]φ[X](式中h[R]和h[X]分别为烷基R 和取代基X对单取代烷烃生成焓Δ_fH⁰(RX)的贡献, φ[R]φ[X]则表示R与X之间的相互作用对Δ_fH⁰(RX)的贡献)来表示单取代烷烃生成焓Δ_fH⁰(RX). 对于双向延伸化合物R1-Y-R2, 其取代基Y位于分子链的中间, 与两个烷基(R1和R2)相连. 此类化合物分子内取代基与烷基之间的相互作用, 较单取代烷烃的相比更为复杂. 因此, Istomin-Palm模型在R1-Y-R2体系中应用必须进行修正. 本文把取代基Y、烷基R1和R2三者之间的相互作用对R1-Y-R2类化合物生成焓Δ_fH⁰(R1-Y-R2)的贡献分为三部分: R1Y与R2之间的相互作用(φ[R2]φ[R1Y]), YR2与R1之间的相互作用(φ[R1]φ[YR2]), 以及两烷基R1与R2之间的相互作用(ψ[R1]ψ[R2]). 用以上三项替换φ[R]φ[X], 扩展Istomin-Palm模型, 建立一个新的经验模型Δ_fH⁰(R1-Y-R2)=h[R1]+h[R2]+h[Y]+φ[R1]φ[YR2]+φ[R2]φ[R1Y]+ψ[R1]ψ[R2], 来表示Δ_fH⁰(R1-Y-R2)(式中h[R1]、h[R2]和h[Y]分别为烷基R1、R2和取代基Y对Δ_fH⁰(R1-Y-R2)的贡献, 后三项则表示烷基R1、R2和取代基Y两两之间相互作用对Δ_fH⁰(R1-Y-R2)的贡献). 进而, 采用本研究组最近报道的相互作用势指数IPI(X)(Wu, Y. X.; Cao, C. Z.; Yuan, H. Chin. J. Chem. Phys. 2012,25 (2), 153.)表示取代基Y对烷基的固有作用(φ[Y]), 从而建立两个定量估算生成焓的通用模型. 其中, 一个用于估算硫醚、仲胺、醚和酮类化合物生成焓, 另一个用于估算酯类化合物生成焓. 这两个模型均得到良好的结果, 与采用G3和G3MP2方法相比具有同样的精度, 还可以避免大量繁琐的计算.     

Use of Retention Data as the First Step in the Identification of Cyclic Organic Peroxides in Temperature-Programmed Gas Chromatography

Temperature-programmed retention indices for eleven cyclic organic peroxides were determined by gas chromatography on slightly polar 5% biphenyl 95% dimethylpolysiloxane columns (DB-5 and Rtx-5MS) at three heating rates (5, 10, and 20° min⁻¹) from 60 to 300°C, using different chromatographs. Cyclic organic diperoxides and triperoxides had nearly constant retention indices when different heating rates and a short isothermal hold time (5 min) before the programmed increase in temperature were used. The usefulness of temperature-programmed retention indices was shown by using the data to predict the retention times and structures of unknown diperoxides or triperoxides derived from ketones. This is the first step in the identification of unknown cyclic organic peroxides, a process would otherwise require the availability of reference compounds. Revised: 7 and 17 November 2005     

Kinetic studies on the formation of cyclic oligomers in poly(ethylene terephthalate)

The mechanism of cyclic oligomer formation has been kinetically studied by determining the rate of the formation of cyclic oligomers during melt of poly(ethylene terephthalate) (PET) at several levels of average molecular weight, which were obtained by fractionation and did not initially contain oligomers. The experimental rate equation of cyclic oligomer formation was introduced and then compared with the rate equation derived theoretically. The close agreement between the two equations suggested that the cyclic oligomer formation takes place according to cyclodepolymerization by the action of hydroxyl end groups in PET. The relation is represented as [C] = m·[OH]₀·t^1–n, where [C] is the concentration of cyclic oligomers, [OH]₀ is the initial concentration of hydroxyl end groups, m and n are constants, and t is melting time. A method has also been developed for separating cyclic oligomers from PET using dimethylformamide (DMF) as a solvent.     

Identification of organic hydroperoxides and hydroperoxy acids in secondary organic aerosol formed during the ozonolysis of different monoterpenes and sesquiterpenes by on‐line analysis using atmospheric pressure chemical ionization ion trap mass spectrometry

On‐line ion trap mass spectrometry (ITMS) enables the real‐time characterization of reaction products of secondary organic aerosol (SOA). The analysis was conducted by directly introducing the aerosol particles into the ion source. Positive‐ion chemical ionization at atmospheric pressure (APCI(+)) ITMS was used for the characterization of constituents of biogenic SOA produced in reaction‐chamber experiments. APCI in the positive‐ion mode usually enables the detection of [M+H]⁺ ions of the individual SOA components. In this paper the identification of organic peroxides from biogenic volatile organic compounds (VOCs) by on‐line APCI‐ITMS is presented. Organic peroxides containing a hydroperoxy group, generated by gas‐phase ozonolysis of monoterpenes (α‐pinene and β‐pinene) and sesquiterpenes (α‐cedrene and α‐copaene), could be detected via on‐line APCI(+)‐MS/MS experiments. A characteristic neutral loss of 34 Da (hydrogen peroxide, H₂O₂) in the on‐line MS/MS spectra is a clear indication for the existence of an organic peroxide, containing a hydroperoxy functional group. Copyright © 2009 John Wiley & Sons, Ltd.     

Tetrahalidometallate(II) Ionic Liquids with More than One Metal: The Effect of Bromide versus Chloride

Fifteen N-butylpyridinium salts – five monometallic [C₄Py]₂[MBr₄] and ten bimetallic [C₄Py]₂[M_0.5^aM_0.5^bBr₄] (M=Co, Cu, Mn, Ni, Zn) – were synthesized, and their structures and thermal and electrochemical properties were studied. All the compounds are ionic liquids (ILs) with melting points between 64 and 101 °C. Powder and single-crystal X-ray diffraction show that all ILs are isostructural. The electrochemical stability windows of the ILs are between 2 and 3 V. The conductivities at room temperature are between 10⁻⁵ and 10⁻⁶ S cm⁻¹. At elevated temperatures, the conductivities reach up to 10⁻⁴ S cm⁻¹ at 70 °C. The structures and properties of the current bromide-based ILs were also compared with those of previous examples using chloride ligands, which illustrated differences and similarities between the two groups of ILs.     

Glycolate and Thioglycolate Complexes of Rhenium and Their Oxidative Elimination of Ethylene and of Glycol

Selenium dioxide and osmium tetroxide are effective reagents and catalysts for olefin oxidation, although, owing to their toxicity, reservations remain as to their applicability.^[1] We are therefore seeking more easily handled metal oxides that are soluble in organic solvents and that are as effective as osmium tetroxide in carrying out stereospecific cis hydroxylation of olefins. The rhenium(VII ) oxide 1 , which has meanwhile become readily accessible, is a favorable candidate.^[2]     

Chemistry of the phenoxathiins VIII. Synthesis of 7-chlorobenzo[1″.2″:5,6:3″,4″:5′,6′] bis[1,4] oxathiino[3,2-b:3′.2′-b′]dipyridine

As a continuation of recent study on the synthesis of a bis[1,4]oxathiinodipyridine ring system, we would now like to report the preparation of 7-chlorobenzo[1″,2″:5,6:3″,4″:5′,6′]-bis[1,4]oxathiino[3,2-b: 3′,2′-b]dipyridine. Although a potentially complex reaction with several products possible, the title compound was formed exclusively, suggesting considerable mechanistic selectivity. The characterization of the product by FT-¹H-nmr as well as its mass spectral fragmentation pathways are also reported.     

Rare examples of base pairing via a protonated pyridine N atom in two salts of N2,N6‐bis(1,3‐dimethylimidazolin‐2‐ylidene)pyridine‐2,6‐diamine

The title compounds, namely 2,6‐bis[(1,3‐dimethylimidazolin‐2‐ylidene)amino]pyridinium perchlorate, C₁₅H₂₄N₇⁺·ClO₄⁻, (I), and bis{2,6‐bis[(1,3‐dimethylimidazolin‐2‐ylidene)amino]pyridinium} μ‐oxido‐bis[trichloridoiron(III)], (C₁₅H₂₄N₇)₂[Fe₂Cl₆O], (II), are structurally unusual examples of the organization of molecular units via base pairing. The cations in salts (I) and (II) are derived from the bisguanidine N²,N⁶‐bis(1,3‐dimethylimidazolin‐2‐ylidene)pyridine‐2,6‐diamine, which associates in centrosymmetric pairs via two N—H...N hydrogen‐bond interactions. N—H...N bridges are formed between the protonated pyridine N atom and one of the nonprotonated guanidine N atoms, with N...H distances of 2.01 (1)–2.10 (1) Å. Compound (I) contains two crystallographically independent cations and anions per asymmetric unit. One of the perchlorate anions is disordered, while the [Fe₂Cl₆O]²⁻ anion lies on an inversion centre.     

Synthesis and 13C-NMR study of pyrazolo[4,5-c] and pyrazolo[4,3-c benzazepines. III

The synthesis of pyrazolo[4,5-c][1]benzazepin-10-ones 10 and 13 and pyrazolo[4,3-c][1]benzazepin-10-ones 11 and 12 is reported. The structure of compounds 10-13 and that of their parent compounds 2-5 ensues from a ¹³C nmr study.     

Design and synthesis of multidentate ligands via metal promoted C-N bond formation processes and their coordination chemistry

This presentation reports some novel examples of organic ring amination reactions via metal mediation. The organic transformations are highly regioselective and can be controlled by the proper selection of the mediator complex. The two isomeric organic ligands viz. HL¹ and HL² were isolated in their pure states by the removal of the metal ions. These were fully characterized. The ligand HL¹ has lowpKa, 8.5. Upon deprotonation, it behaves as a potentialbis chelating N,N,N-donors. The coordination chemistry of the HL¹ ligand involving some 3d-metal ions is described. Two unusual low-spin complexes of manganese(II) and iron(III) are reported. The ferric complex displayed a rhombic EPR while, the corresponding manganese compound showed a complex pattern due to hyperfine coupling. All the complexes displayed large number of redox responses. A brief mention about the future projection of this work is noted.     

Quino[7,8-h]quinoline,a New Type of “Proton Sponge”

So far, “proton sponges” have been defined as bis(dialkylamino)arenes whose dialkylamino groups are in close spatial proximity.^[1] The unusual basicity of these compounds is ascribed to the destabilizing overlap of the lone electron pairs on the nitrogen atoms, to the formation of especially strong hydrogen bonds in the monoprotonated diamines, and to the hydrophobic shielding of these hydrogen bonds. In order to differentiate and assess the relative importance of these factors, we were interested in quino[7,8-h]quinoline 1 , whose nitrogen atoms exhibit a mutual orientation similar to that in 1,8-bis(dimethylamino)naphthalene 2 (“proton sponge”). In contrast to 2 , however, 1 lacks the hydrophobic shielding of the hydrogen bonds of its monoprotonated derivative. This shielding is considered to be responsible for the low rates of proton transfer, which make the “proton sponges” reported so far unsuitable as auxiliary bases in chemical reactions.