Chalcogen exchange in chalcogen–nitrogen π-heterocycles

The procedures for synthesizing fused 1,2,5-chalcogenadi-azoles and 1,2,3-dithiazoles by direct exchange of one chalcogen atom for another, their scope and reaction pathways are discussed in this focus review.     

Charge-transfer complexes of benzanilides with π-acceptors

Spectrophotometric studies of several substituted benzanilides as electron donors with tetracyanoethylene (TCNE) and 2,3-dichloro-5,6-dicyanobenzoquinone (DDQ) as electron acceptors have given results that are consistent with an interpretation of 1:1 charge-transfer (CT) complexes. The nature of interaction as well as the substituent effects on the CT complexation are discussed.     

An ab initio investigation of chalcogen–hydride interactions involving HXeH as a chalcogen bond acceptor

This work presents an ab initio study on chalcogen–hydride interactions in several binary complexes of chalcogen-containing molecules with HXeH. The geometries, H–Xe stretching frequencies and interaction energies of XCY···HXeH binary complexes are investigated at MP2/aug-cc-pVTZ and CCSD(T)/aug-cc-pVTZ levels of theory, where X = O, S, Se, Te and Y = S, Se, Te. For each XCY···HXeH complex, a chalcogen–hydride bond is formed between the negatively charged hydrogen atom of the HXeH molecule and the most positive electrostatic potential region (σ-hole) on the surface of the interacting atom Y. Upon complex formation, a notable blue shift is found for the H–Xe stretch vibration. This result reveals that there is a stronger H^?(XeH)⁺ ion-pair character in XCY···HXeH complexes than in free HXeH molecule. In order to shed light on the origin of the chalcogen–hydride interactions, molecular electrostatic potential, quantum theory of atoms in molecules and interaction energy decomposition analyses are performed. Cooperative effects between a conventional chalcogen bond and the chalcogen–hydride interaction in OCY···OCY···HXeH complexes are also investigated.     

Molecular dynamics comparative study of methane–nitrogen and methane–nitrogen–ethane systems

This work concerns the site–site interaction study of 256 particles using the Buckingham potential model. We have calculated the new parameters of the Buckingham potential using an iterative algorithm with a mean square method. This adapted model allows determining the characteristics for each state point. We have applied this model to study the liquefied natural gas LNG properties for methane-nitrogen and methane–nitrogen–ethane mixtures by molecular dynamics. We have calculated the thermodynamic, dynamic and structural properties for both the microcanonical NVT and the isothermal-isobaric NPT ensembles of binary and ternary systems from the SP₁ to SP₉ points. Then, we have compared the results between binary and ternary systems. We have obtained a good prediction on transport properties. From the calculated values of self-diffusion coefficient and viscosity, we have confirmed the liquid state of the liquefied natural gas LNG system.     

Spectrophotometric Determination of Cimetidine through Charge-transfer Reaction with 1,5-Dichloroanthraquinone as a π-Electron Acceptor

Cimetidine reacting with 1,5-dichloroanthraquinone in acetone solution can produce a charge-transfer complex that shows a strong absorption peak at 343 nm. The absorption value at 343 nm increased with cimetidine concentration in the range of 0.01—0.5 μg/mL, with regression coefficient of 0.9995 and detection limit of 0.006 μg/mL. This simple and sensitive method has been successfully applied to determine cimetidine in tablets and capsules, with average recovery of (98.47±0.92)% and (97.07±1.16)%, respectively. Furthermore, the mole ratio of the complex between cimetidine and 1,5-dichloroanthraquinone is 2∶1, and the mechanism of charge-transfer reaction is explored.     

Coordination chemistry and biological activity of bidentate and quadridentate nitrogen–sulfur donor ligands and their complexes

The ligand S-benzyldithiocarbazate (SBDTC) acts as a bidentate sulfur–nitrogen chelating agent. The reaction of Sn^II or Sb^III with SBDTC under alkaline conditions gives complexes of composition [Sn(SBDTCA)₂] · 2H₂O and [Sb(SBDTCA)Cl₂ · 2H₂O]. A quadridentate Schiff base of SBDTC with benzil, having a donor sequence SNNS, yields complexes, [Cd(SNNS)] and [Zr(O)(SNNS) · H₂O]. The ligands and the complexes have been characterized by elemental analyses, i.r., u.v.–vis., molar conductance measurements and ¹H-n.m.r. spectroscopy. SBDTC, Sn^II and Sb^III complexes and the SNNS Schiff base together with its Cd^II and Zr^IV complexes display significant antifungal, antibacterial and anti-cancer activity. The Sn^II complex and the SNNS free Schiff base were very effective against Melanoma (skin cancer cells). The SBDTC and its Sn^II complex were also very effective against Renal carcinoma (kidney cancer cells). The results have been compared with those of the uncomplexed metal salts and the free ligands. The minimum concentrations for the evaluation of the above activities for CD₅₀ of the samples were in the 1.0–15 g cm^–3 range.     

Charge-transfer Salt of Tungstogermanate Heteropolyanion and Dibenzotetrathiofulvalene

lINTRODUCTIONSincetheobservationofametallicstateinthechargetransfer(CT)salt,(TTF)(TCNQ)(l:(TTF=tetrathiofulva1eneiTCNQ=7,7,"8,8-tetracyano-p-quin-odimethane)andasuperconductingstateintheBechgaardsaltsF27,(TMTSF)2X,2EXPERIMENTAL2'1Preparati0n0fchargetransfersaltThedbtf(C,'H,S')wasobtainedac-cordingtoreference[6iandexaminedby1HNMRspectrosc0py.t(C'H,)'Nj'GeW,,-O',waspreparedaccordingtoreferencet73andcheckedwithIRspectraandpolaro-graphicmethods.TheCTsaltwassynthesizedbyco…     

Synthesis of silicon–nitrogen derivatives in quasi-interstellar conditions

At 2–4·10^–5 T, a silicon wafer is the target of a 5–10 keV molecular beam of dinitrogen. The products are extracted by an electric field, and analysed by mass. The ions of this primary spectrum are dissociated in a Kr collision chamber. From the fragments thus obtained, one deduces compositions for the secondary ions, and therefore for the primary products. This is helped by the presence, in silicon, of the isotopes ²⁸Si, ²⁹Si and ³⁰Si. Beside the clusters Si_n (n = 1–7), complex molecular species are thus obtained, such as Si₅N₄⁺, Si₅N₄H⁺, Si₅N₄H₂⁺. © 2000 Académie des sciences / Éditions scientifiques et médicales Elsevier SASinterstellar dust / interstellar molecules / atomic impact / silicon / nitrogen derivatives     

Studies on coordination chemistry of a nitrogen–sulfur donor ligand with lighter and heavier metal ions and biological activities of its complexes

Complexes of S-benzyldithiocarbazate (SBDTC) with lighter and heavier metals, viz., Cr^III, Fe^III, Sb^III, Zr^IV, Th^IV and U^VI have been prepared and characterized by elemental analyses, conductivity measurements, and spectral studies. The complexes: [Cr(SBDTCA)₃],^** [Fe(SBDTCA)₃], [Sb(SBDTCA)₃], [Sb(SBDTCA)₂Cl · H₂O], [Zr(O)(SBDTCA)₂ · H₂O], [Th(SBDTCA)(NO₃)₃ · H₂O)], and [U(O)₂(SBDTCA)₂] were all prepared in alkaline media. They were all hexa-coordinated with bidentate, uninegative chelation of the ligand. [Fe(SBDTCA)₃], [Sb(SBDTCA)₃] and [Sb(SBDTCA)₂Cl · H₂O] were strongly effective against bacteria giving clear inhibition zones with Pseudomonas aeruginosa and Bacillus cereus. The compounds showed poor antifungal activity. The antimony complexes were strongly cytotoxic against leukemic cells with CD₅₀ values of 3.2–6.7 g cm^–3 as compared to the CD₅₀ value of 14.5 g cm^–3 of the free SbCl₃ molecule.     

Charge-transfer complexes of Cu(II)/HD analogue in sol–gel sensors

An optically transparent xerogel encapsulating Cu(II) acetate is fabricated to detect mustard gas (HD) analogues via a charge-transfer mechanism. A fast response (color change from sky blue to canary yellow) is observed for the chlorinated sulfide, and is accompanied by an absorption band at 370–420 nm. MO calculations revealed that the chlorinated HD analogue displays a charge-transfer transition extended from sulfur to chlorine atom. A 1:1 complex of Cu(II)/HD analogue is preferred. For a colorimetric sol–gel detector prepared at pH 3, the detection limit of HD analogue is calibrated at 0.03 μl per 1.5 ml sensor volume.     

Rapid Synthesis of π-Phenylglycine by Carboxylation of π-Lithiobenzylisocyanide

An expanding field of interest in nuclear medicine is the preparation of radiopharmaceuticals labelled with cyclorrn produced isotopes of short half life.^1–3 In an investigation to prepare ¹¹C-labelled amino acids we developed a new and repid synthesis for the preparation of a-phenylglycine. The preparation of other amino acids by this route is under investigation. α-Lithiobenzylisocyande⁴ was treated with carbondioxyde and the intermediate was hydrolysed to the amino acid. The overall yield (75–808) was accomplished in 50–70 minutes.⁺     

Phase diagram and crystal chemistry of the La–Ca–Co–O system

The phase diagram of the La–Ca–Co–O system at 885 °C in air has been determined. The system consists of two materials that have interesting thermoelectric properties, namely, the misfit layered thermoelectric oxide solid solution, (Ca,La)₃Co₄O₉, and Ca₃Co₂O₆ which consists of 1D chains of alternating CoO₆ trigonal prism and CoO₆ octahedra. The reported La₂CaO₄ and the Ca-doped (La,Ca)₂CoO_4−z phases were not found at 885 °C. As a result of the absence of these phases, the phase diagram is significantly different from that reported at 1100 °C. Small solid solution regions of (La_1−xCa_x)₂O_3−z (0 ≤ x ≤ 0.08), (Ca_1−xLa_x)₃Co₄O₉ (0 ≤ x ≤ 0.07), and (La_1−xCa_x)CoO_3−z (0 ≤ x ≤ 0.2) were established.     

Solid-state NMR studies of host–guest chemistry in metal-organic frameworks

Metal-organic frameworks (MOFs) are an emerging class of porous materials with potential applications in a wide variety of fields. The knowledge about the detailed interactions between MOFs and guest molecules is critical for the understanding of their structure-property relationships at working conditions. In this review, recent advances for solid-state NMR studies of host–guest chemistry of MOFs in the application fields of gaseous adsorption, chemical separation, drug delivery, chemical sensor, and heterogeneous catalysis were briefly introduced. The adsorption property and dynamic behavior of adsorbed gases confined inside the MOFs channels were elucidated from variable-temperature (VT) solid-state NMR. Moreover, the detailed mechanism of gas-phase and liquid-phase adsorptive separations on MOFs adsorbents was uncovered on the basis of solid-state NMR measurements. Multi-nuclear ¹H, ¹³C, ¹⁵N, and ³¹P MAS NMR was utilized to explore the interactions between drug molecules and MOFs at the atomic scale to monitor the controlled release process of drugs. Furthermore, the investigation of the interactions between guest molecules and MOFs in the application areas of chemical sensor, toxic chemicals removal, and catalysis using solid-state NMR was briefly discussed as well.     

A glimpse at the chemistry of GeH2 in solution. Direct detection of an intramolecular germylene-alkene π-complex

The photochemistry of 3-methyl-4-phenyl-1-germacyclopent-3-ene (4) and a deuterium-labeled derivative (4-d(2)) has been studied in solution by steady state and laser flash photolysis methods, with the goal of detecting the parent germylene (GeH(2)) directly and studying its reactivity in solution. Photolysis of 4 in C(6)D(12) containing acetic acid (AcOH) or methanol (MeOH) affords 2-methyl-3-phenyl-1,3-butadiene (6) and the O-H insertion products ROGeH(3) (R = Me or Ac) in yields of ca. 60% and 15-30%, respectively, along with numerous minor products which the deuterium-labeling studies suggest are mainly derived from hydrogermylation processes involving GeH(2) and diene 6. The reaction with AcOH also affords H(2) in ca. 20% yield, while HD is obtained from 4-d(2) under similar conditions. Photolysis of 4 in THF-d(8) containing AcOH affords AcOGeH(3) and 6 exclusively, indicating that the nucleophilic solvent assists the extrusion of GeH(2) from 4 and alters the mechanism of the trapping reaction with AcOH compared to that in cyclohexane. Laser flash photolysis of 4 in hexanes yields a promptly formed transient exhibiting λ(max) ≈ 460 nm, which decays on the microsecond time scale with the concomitant growth of a second, much longer-lived transient exhibiting λ(max) ≈ 390 nm. The spectrum and reactivity of the 460 nm species toward various germylene trapping agents are inconsistent with those expected for free GeH(2); rather, the transient is assigned to an intramolecular Ge(II)-alkene π-complex of one of the isomeric substituted hydridogermylenes derived from a solvent-cage reaction between GeH(2) and its diene (6) coproduct, formed by addition of HGe-H across one of the C=C bonds. These conclusions are supported by the results of DFT calculations of the thermochemistry associated with π-complexation of GeH(2) with 6 and the formation of the isomeric vinylgermiranes and 1,2-hydrogermylation products. A different species is observed upon laser photolysis of 4 in THF solution and is assigned to the GeH(2)-THF complex on the basis of its UV-vis spectrum and rate constants for its reaction with AcOH and AcOD.