Short Strong Hydrogen Bonds can Hinder Complex Formation: A Stability and Structure Study of Copper(II) Alkyl-N-iminodiacetic Acid Complexes in Aqueous Systems and Solid State
暂无分享,去创建一个
[1] D. Lundberg,et al. EXAFS Study on the Coordination Chemistry of the Solvated Copper(II) Ion in a Series of Oxygen Donor Solvents , 2020, Inorganic chemistry.
[2] Komplexone , 2019, Springer Reference Medizin.
[3] H. Edlund,et al. Electrochemical recovery of copper complexed by DTPA and C12‐DTPA from aqueous solution using a membrane cell , 2018 .
[4] H. Edlund,et al. Electrochemical treatment of copper complexed by chelating agent and chelating surfactant in alkaline solution using a membrane cell , 2017 .
[5] Leif Häggman,et al. The influence of short strong hydrogen bonding on the structure and the physicochemical properties of alkyl-N-iminodiacetic acids in solid state and aqueous systems. , 2003, Journal of the American Chemical Society.
[6] A. Ankudinov,et al. RELATIVISTIC CALCULATIONS OF SPIN-DEPENDENT X-RAY-ABSORPTION SPECTRA , 1997 .
[7] Ankudinov,et al. Multiple-scattering calculations of x-ray-absorption spectra. , 1995, Physical review. B, Condensed matter.
[8] K. Hodgson,et al. An EXAFS spectroscopic study of solvates of copper(I) and copper(II) in acetonitrile, dimethyl sulfoxide, pyridine, and tetrahydrothiophene solutions and a large-angle x-ray scattering study of the copper(II) acetonitrile solvate in solution , 1993 .
[9] C. Sudha,et al. Studies on copper(II) and zinc(II) mixed ligand complexes involving some potentially tridentate ligands , 1992 .
[10] J. Kiss,et al. Protonation and complex formation equilibria of N-(phenylcarbamoylmethyl)iminodiacetic acid derivatives—I. The complexes of HIDA and diethylcarbamoyl-MIDA , 1992 .
[11] Richard W. Taylor,et al. Complexation kinetics of highly substituted acyclic, monocyclic, and bicyclic tetraamines with copper(II) in basic aqueous media , 1986 .
[12] A. Lewenstam,et al. Effect of some chelating ligands on the potential response of the chalcocite copper ion-selective electrode , 1984 .
[13] R. Stella,et al. A study of copper and cadmium iminodiacetate complexes by ion-selective electrodes and application to cadmium monitoring , 1983 .
[14] F. Riggi,et al. Thermodynamic and spectroscopic properties of mixed complexes in aqueous solution. Copper(II) complexes of 2,2'-bipyridyl and iminodiacetic or pyridine-2,6-dicarboxylic acid , 1979 .
[15] Allen WesleyD.,et al. Adsorbing Colloid Flotation of Cu(II) with a Chelating Surfactant , 1979 .
[16] D. W. Margerum,et al. Role of coordinated hydroxide ion in configurational conversions of tetraamine macrocyclic ligand complexes of copper(II) , 1979 .
[17] L. Pettit,et al. CO-ORDINATION OF SILVER(I) TO OLEFINIC BONDS, COMPLEX FORMATION BETWEEN COBALT(II), NICKEL(II), COPPER(II), ZINC(II), CADMIUM(II), AND SILVER(I) AND SOME UNSATURATED DERIVATIVES OF ACETIC AND IMINODIACETIC ACIDS , 1975 .
[18] L. Pettit,et al. Co-ordination of silver(I) to olefinic bonds. Complex formation between cobalt(II), nickel(II), copper(II), zinc(II), cadmium(II), and silver(I) and some unsaturated derivatives of acetic and iminodiacetic acids , 1975 .
[19] R. J. Angelici,et al. Equilibrium studies of copper(II) complexes of iminodiacetates with amino acid esters and the kinetics of ester hydrolysis , 1969 .
[20] P. Gouzerh,et al. No 667. --Préparation et étude en solution de nouveaux amino diacides complexants. , 1966 .
[21] G. Anderegg. Komplexone XXXVI. Reakinsenthalpie und ‐entropie bei der Bildung der Metallkomplexe der höheren EDTA‐Homologen , 1964 .
[22] D. W. Margerum,et al. Multidentate Ligand Kinetics. V. Copper(II) and Cyclohexylenediaminetetraacetatonickelate(II) , 1963 .
[23] D. W. Margerum,et al. Multidentate Ligand Kinetics. I. Copper(II) and Ethylenediaminetetraacetatonickelate(II) , 1961 .
[24] G. Anderegg,et al. Komplexone XXVI. Über die Koordinationstendenz von N-substituierten Iminodiessigsäuren , 1955 .
[25] A. Martell,et al. Stability of Metal Chelates. I. Iminodiacetic and Iminodipropionic Acids , 1952 .