Rapid synthesis of α-ketoamides using microwave irradiation-simultaneous cooling method

Microwave-assisted acyl chloride-isonitrile condensation and CaCO₃-mediated hydrolysis constitute a one-pot, 2-minute process to prepare α-ketoamides.     

Electrochemical oxidation of sulphapyridine at a pyrolytic graphite electrode

The electrochemical oxidation of sulphapyridine at a pyrolytic graphite electrode was studied over a wide pH range. Sulphapyridine is oxidized in an irreversible reaction involving two electrons and two protons to give an electroactive product. On the basis of voltammetric, spectral and coulometric studies and product identification, a tentative mechanism is suggested.     

The chemistry of pyridine thiols and related ligands, Part 5. Synthesis and spectroscopy of nickel(II) and copper(II) complexes containing 1-oxopyridine-2-thione and 2,2′-bipyridine or 1,10-phenanthroline

Summary Reactions of bis(1-oxopyridine-2-thione) Ni^II or Cu^II with 2,2-bipyridine (bipy) or 1,10-phenanthroline (phen) yield complexes of stoichiometry: Ni(C₅H₄NOS)₂L {L = bipy, two isomers: (1) and (2), L = phen, one isomer (3)} and Cu(C₅H₄NOS)₂(phen)·0.75CHCl₃ (4). The spectroscopy (i.r., u.v.-vis., e.s.r.) and magnetism studies of the above complexes are described. On the basis of conductivity, the Cu^II-phen complex has been formulated as [Cu(C₅H₄NOS)(phen)₂][Cu(C₅H₄NOS)₃]·1.5CHCl₃ (4). The vis. absorption spectra support similar octahedral structures for the minor bipy isomer (2) and for the Ni^II-phen complex [(3)], whereas the major isomer [(1)] has a different structure. The e.s.r. spectrum of the Cu^II-phen complex (4) is commensurate with an elongated octahedral structure. New methods for the preparation and spectroscopy of M(C₅H₄NOS)₂ (M = Mn, Ni, Cu or Zn) compounds have been investigated.     

A note on the eigenvalues of p‐fractional Hardy–Sobolev operator with indefinite weight

In this article, we study the eigenvalues of p‐fractional Hardy operator where , , , and Ω is an unbounded domain in with Lipschitz boundary containing 0. The weight function V may change sign and may have singular points. We also show that the least positive eigenvalue is simple and it is uniquely associated to a nonnegative eigenfunction. Moreover, we proved that there exists a sequence of eigenvalues as .     

Studies on 1,10-Phenanthroline Complexes of Some Hydroxyaryltellurium Trihalides

The synthesis and structural features of some newly synthesized 1,10-phenanthroline complexes of p-hydroxyphenyl-and 3-methyl-4-hydroxyphenyltellurium trihalides (chlorides, bromides, and iodides) are reported. The resulting complexes have been subjected to elemental analyses, conductance and cryoscopic measurements, infra-red and proton magnetic resonance spectral studies. Solution studies reveal the weak to 1:1 electrolyte type behavior of these complexes in solution. Spectral studies indicate the linkage of phenanthroline to the tellurium atom through the nitrogen atoms. Central tellurium atom in these complexes is hexa-coordinated in an octahedral way.     

Structural designing,spectral and computational studies of bioactive Schiff's base ligand and its transition metal complexes

Transition metal complexes of Mn(II) and Ni(II) have been synthesized with novel bioactive Schiff's base ligand. Schiff's base ligand i.e. benzoylacetone‐bis(2‐amino‐4‐methylbenzothioazole) has been synthesized via condensation reaction between 2‐amino‐4‐methylbenzothioazole and benzoylacetone in 2:1 ratio, respectively. Synthesized ligand has been characterized using elemental analysis, infra‐red, ¹H–NMR and mass spectroscopy techniques. Characterization of complexes was based on magnetic moment, molar conductance, elemental analysis, electronic spectra, infra‐red and EPR spectroscopic techniques. Molar conductance data suggest that metal complexes are non‐electrolytic in nature. Therefore, these complexes are formulated as [M(L)X₂], where M = Mn(II), Ni(II), L = Schiff's base ligand, X = Cl^?, CH₃COO^?, NO₃^?. Data of characterization study suggest octahedral geometry for Mn(II) and Ni(II) complexes. Geometry of metal complexes was also optimized with the help of computational study i.e. molecular modelling. Computational study also suggests octahedral geometry for complexes. Free ligand as well as its all metal complexes have been screened against the growth of pathogenic bacteria (E.coli, S.aureus) and fungi (C.albicans, C.krusei, C.parapsilosis, C.tropicalis) to assess their inhibition potential. The inhibition data revealed that metal complexes exhibit higher inhibition potential against the growth of bacteria and fungi microorganisms than free ligand.