Complex-forming properties of substituted N-hydroxyacetoacetanilides with bivalent and tervalent metal ions

From spectroscopic studies as well as from the stability constants of their complexes with metal ions, it has been observed that substituted N-hydroxyacetoacetanilides do not enolize, because of strong hydrogen bonding in the hydroxamic moiety CH(3).CO.CH(2).CO.N(OH).R hindering the movement of the CH(3).CO.CH(2)- group. The ligands thus behave as bidentate in contrast to the expected terdentate nature. The stability constants of their complexes are comparable with those for complexes of other ligands in which oxygen is the donor.     

Study of alkali metal cations binding selectivity of beta-cyclodextrin by ESI-MS

Cyclodextrins (CDs), cyclic oligosaccharides commonly composed of six, seven or eight (alpha, beta, and gamma respectively) D-glucopyranosyl units connected by alpha-(1,4)- glycosidic linkages, have the ability to form inclusion complexes with a wide range of substrates in aqueous solution. This property has led to their applications in different areas such as enzyme mimics, catalysis and the encapsulation. of drugs. ESI-MS has begun to be viewed as a useful tool for investigating the general area of molecular recognition thus providing a powerful mean for the analysis of a wide array of host-guest complexes and other non covalent complexes present in solution. The evaluation of the binding selectivity of beta-cyclodextrin towards the first group alkali cations is reported. The estimation of the affinity degrees has been achieved by competition ESI-MS experiments. In these experiments beta-CD was incubated at the presence of two different cations at the same time, and the ratio of the mass peaks corresponding to the two complexes was calculated. In general, it appears a much larger affinity of the beta-cyclodextrin molecule with sodium with respect to all the other alkaline cations, thus giving evidence that it is the size of the beta-cyclodextrin ring in relation with the cationic radius, which drives the formation of what, at this point, could be defined as an inclusion complex.     

Thermal characterization of Flemion® membranes substituted by alkali metal cations

The thermal behavior of perfluorosulfonated membranes of three equivalent mass (EW=910, 1000 and 1100 g eq⁻¹) has been studied for membranes in acid form and in the alkali metal countercations substituted samples. The water contents of the membranes decrease progressively with increasing EW and the countercations charge density. The monovalent cations substitutions increase the membranes thermal stability. DSC curves show a single endothermic peak around 120°C that give low peak temperature for low EW and high peak temperature for large cations size. The membrane mechanical properties changed for different EW and temperatures of membranes. Stress-strain analysis showed that K⁺ substituted membranes at both temperatures present a highest YM compared to the other alkali cation substitutions. The thermal properties of perfluorosulfonated membranes depend on the water contents, cation size, temperature and also on EW value.     

Ketones substituted with an alkali metal. Isolation and some properties

With lithium, sodium, or potassium some derivatives of aliphatic ketones have been isolated. Their IR spectra in various media have been recorded, and in strongly solvating solvents confirm the enolate structures. The interaction of metalated 2,2-dimethyl-3-butanones with t-butoxides of the same alkali metal was demonstrated. Lithio-2,2-dimethyl-3-butanone reacted with alkoxides of heavier alkali metals via a metal—metal exchange reaction with formation of sodio- or potassio-2,2-dimethyl-3-butanone.     

Acid-base properties of substituted tetraphenylmethylenediphosphine dioxides

Conclusions Some tetraphenylmethylenediphosphine dioxides, substituted in the methylene bridge, were subjected to potentiometric titration in nitromethane with perchloric acid. The obtained values of the pK _a basicity constants (CH₃NO₂) obey a linear relationship with the ^* constants of the substituents.Translated from Izvestiya Akademii Nauk SSSR, Seriya Khimicheskaya, No. 1, pp. 199–201, January, 1972.     

The selectivity of active carbons modified by fullerenes with respect to mixtures of metal cations in aqueous solutions

The separating ability of active carbons and active carbons modified with fullerenes with respect to mixtures of nonferrous metal cations was studied. The selectivity series for the extraction of cations from aqueous solutions was Ag⁺ > Cu²⁺ > Pb²⁺. The selectivity of adsorption by active carbon modified with fullerenes was higher than that characteristic of the initial adsorbent, especially for the extraction of silver ions from a mixture of silver and copper cations.     

Relative binding affinities of alkali metal cations to

The binding affinity and selectivity of a new ionophore, [1(8)]starand (1), toward alkali metal cations in methanol were examined through NMR titration experiments and free energy perturbation (FEP) and molecular dynamics simulations. The preference was determined to be K(+) > Rb(+) > Cs(+) > Na(+) > Li(+) in both FEP simulations and NMR experiments. The FEP simulation results were able to predict the relative binding free energies with errors less than 0.13 kcal/mol, except for the case between Li(+) and Na(+). The cation selectivity was rationalized by analyzing the radial distribution functions of the M-O and M-C distances of free metal cations in methanol and those of metal-ionophore complexes in methanol.     

Organometallic ionophore for alkali metal cations

Complexes of a novel synthetic organometallic ionophore with lithium and sodium cations have been characterized by single-crystal X-ray diffraction. The crystal structure of the lithium complex consists of cation-liganddimers with a tetrahedral coordination around Li. The sodium complex reveals a different structure type consisting of cation-ligandtrimers, with water molecules being included between the trimeric entities. The coordination sphere around the Na ions has a distorted octahedral symmetry. It is anticipated that the observed structures of dinuclear Li and trinuclear Na complexes represent possible modes of aggregation of the cation-ligand entities in lipophilic media.     

Salt forms of sulfadiazine with alkali metal and organic cations

The structures of four salt forms of sulfadiazine (SDH) with alkali metal cations are presented. Three contain the deprotonated SD anion (C₁₀H₉N₄O₂S). These are the discrete complex diaqua{4‐[(pyrimidin‐2‐ylazanidyl‐κN¹)sulfonyl‐κO]aniline}lithium(I), [Li(SD)(H₂O)₂], (I), and the coordination polymers poly[{μ₃‐4‐[(pyrimidin‐2‐ylazanidyl)sulfonyl]aniline}sodium(I)], [Na(SD)]_n, (II), and poly[diaqua{μ₃‐4‐[(pyrimidin‐2‐ylazanidyl)sulfonyl]aniline}potassium(I)], [K(SD)(H₂O)₂]_n, (III). Na complex (II) is a three‐dimensional coordination polymer, whilst K complex (III) has two crystallographically independent [K(SD)(H₂O)₂] units per asymmetric unit (Z′ = 2) and gives a two‐dimensional coordination polymer whose layers propagate parallel to the crystallographic ab plane. The different bonding modes of the SD anion in these three complexes is discussed. Structure (IV) contains protonated SDH₂ cations {4‐[(pyrimidin‐2‐yl)sulfamoyl]anilinium, C₁₀H₁₁N₄O₂S} and the Orange G dianion [OG, 7‐oxo‐8‐(phenylhydrazinylidene)naphthalene‐1,3‐disulfonate, C₁₆H₁₀N₂O₇S₂], namely, 4‐[(pyrimidin‐2‐yl)sulfamoyl]anilinium tetraaqua[7‐oxo‐8‐(phenylhydrazinylidene)naphthalene‐1,3‐disulfonato]sodium(I) sesquihydrate, (SDH₂)[Na(OG)(H₂O)₄]·1.5H₂O. The [Na(OG)(H₂O)₄]₂ dimers have antiparallel naphthyl ring structures joined through two Na centres that bond to the hydrazone anions through the O atoms of the ketone and sulfonate substituents. The structures of the salts formed on reaction of SDH with 2‐aminopyridine and ethanolamine are also presented as 2‐aminopyridinium 4‐[(pyrimidin‐2‐ylazanidyl)sulfonyl]aniline, [C₅H₇N₂][SD], (V), and ethanolaminium 4‐[(pyrimidin‐2‐ylazanidyl)sulfonyl]aniline monohydrate, [HOCH₂CH₂NH₃][SD]·H₂O, (VI), respectively. Structure (V) features a heterodimeric R₂²(8) hydrogen‐bond motif between the cation and the anion, whilst structure (VI) has a tetrameric core of two cations linked by a central R₂²(10) hydrogen‐bonded motif which supports two anions linked to this core by R₃³(8) motifs.     

The interaction of alkali metal cations with oxygen-containing ligands

Ab initio SCF calculations on the interaction of Li⁺ cation with H₂O and H₂CO using two basis sets are presented. Partitioning of SCF energies of interaction into Coulomb-, exchange- and delocalization energies has been performed. Coulomb- and delocalization energies are compared with classical electrostatic and polarization energies. A detailed analysis of the calculated wave functions demonstrates that in the complexes investigated here, charge transfer is of minor importance only. Polarization of the molecules in the strong inhomogeneous field of the cation leads to complicated electron density rearrangements which can be interpreted most easily in terms of polarization of individual localized MO's.     

Phosphorus-containing podands. 9. Synthesis of oligoethylene glycol bis(diphenylphosphinylethyl) esters and their complexing properties with respect to alkali metal cations in a low-polarity solvent

The complexing ability of phosphoryl-containing monopodands with the general formula Ph₂P(O)CH₂CH₂O(CH₂CH₂O)_nCH₂CH₂P(O)Ph₂ (n=0–5, 6.4, 8.7, 13.2) with respect to alkali metal cations was investigated conductometrically in tetrahydrofuran:chloroform mixed solvent (4:1, vol.) at 25°C. It was found that ligands of this type are efficient complexing agents relative to all alkali metal cations, and the monopodand with n=0 also exhibits elevated Li/Na and Li/K selectivity. The effect of the structure, particularly the "rigidity" of the terminal fragments of the monopodands, on their complexing capacity was discussed. The method of synthesis of this type of ligand was described.See [1] for preceding communication.Institute of Physiologically Active Substances, Russian Academy of Sciences, 142432 Chernogolovka. Scientific-Research Institute of Chemical Reagents and Special-Purity Chemicals, Moscow. Translated from Izvestiya Akademii Nauk, Seriya Khimicheskaya, No. 5, pp. 1161–1167, May, 1992.     

Synthesis and selectivity of sym-hydroxydibenzo-14crown-4 ionophores for protons,alkali metal cations,and alkaline earth cations in polymeric membranes

Six derivatives of sym-hydroxydibenzo-14-crown-4 have been prepared and incorporated into solvent-polymeric membranes. Responses of the membranes to protons, alkali metal cations, and alkaline earth cations have been determined. The preferred uptake of protons is attributed to proton complexation by stable crown ether alcohol and diol monohydrate species.     

Energetics and bonding in aluminosilicate rings with alkali metal and alkaline-Earth metal charge-compensating cations

The stabilizing effect of alkali and alkaline-earth metal ions on the oxygen donors of four- and six-membered faujausite-like rings has been calculated in terms of Kohn-Sham core-level (O1s) energy shifts with respect to these same complexes without cations. The results confirm and complement earlier investigations by Vayssilov and co-workers where Na(+) and K(+) were the only complexing cations. The oxygen donor centers in six-membered rings are stabilized by -3.6 ± 0.4, -3.9 ± 0.5, -7.3 ± 0.1, and -7.6 ± 0.2 eV by K(+), Na(+), Ca(2+), and Mg(2+) adions, respectively. The energy shifts are even greater for four-membered rings where the stabilization effects attain -3.7 ± 0.1, -4.1 ± 0.1, -8.1 ± 0.1, and -9.0 ± 0.1 eV, respectively. These effects are also observed on the low-lying σ-bonding and antibonding molecular orbitals (MOs) of the oxygen framework, but in a less systematic fashion. Clear relationships with the core-level shifts are found when the effects of alkali metal complexation are evaluated through electron localization/delocalization indices, which are defined in terms of the whole wave function and not just of the individual orbitals. Complexation with cations not only involves a small but significant electron sharing of the cation with the oxygen atoms in the ring but also enhances electron exchange among oxygen atoms while reducing that between the O atoms and the Si or Al atoms bonded to them. Such changes slightly increase from Na to K and from Mg to Ca, whereas they are significantly enhanced for alkaline-earth metals relative to alkali metals. With respect to Al-free complexes, Si/Al substitution and cation charge compensation generally enhance electron delocalization among the O atoms, except between those that are linked through an Al atom, and cause either an increased or a decreased Si-O ionicity (smaller/higher electron exchange) depending on the position of O in the chain relative to the Al atom(s). The generally increased electron delocalization among O atoms in the ring is induced by significant electron transfer from the adsorbed metal to the atoms in the ring. This same transfer establishes an electric field that leads to a noticeable change in the ring-atom core-level energies. The observed shifts are larger for the oxygen atoms because, being negatively charged, they are more easily polarizable than Al and Si. The enhanced electron delocalization among O atoms upon cation complexation is also manifest in Pauling's double-bond nature of the bent σ-bonding MO between nonadjacent oxygen centers in O-based ring structures.     

Ester derivatives of hexahomotrioxacalix[3]naphthalenes: conformational and binding properties with alkali metal cations

The syntheses of the triesters formed between ethyl bromoacetate and hexahomotrioxacalix[3]naphthalene 8, and its tert-butyl analogue 11, are described. Depending on the conditions employed, cone or partial cone conformers are produced. The conformations appear to have some influence on their complexation in neutral medium, with alkali metal cations. The X-ray structure of the partial cone triester 10 is presented.     

Phosphorus-containing podands 4. Effect of polyether chain length of oligoethylene glycol bis(ortho-diphenylphosphinylmethyl)phenyl ethers on their complex-forming and selective properties with respect to alkali metal cations

Alkylation of o-(diphenylphosphinylmethyl)phenol by oligoethylene glycol ditosylates leads to a series of acyclic polyether complexing agents (podands) with phosphinylmethylphenyl terminal groups. A conductometric method in tetrahydrofuranchloroform (41 by volume) has been used to determine the stability constants of the podands with alkali metal 2,4-dinitrophenoxides. Several of the prepared ligands exhibited a high Li/Na, Na/K, and Li/K selectivity. For lithium and sodium cations, the curve of complex-forming ability against the overall number of donor centers in the structure of the podand has a maximum for the case of tetraethylene glycol bis(o-diphenylphosphinylmethyl)phenyl ether. For lithium cations, this compound surpasses the crown ethers in terms of its effectiveness and is the most powerful of the phosphoryl-containing complexing agents. For potassium, rubidium, and cesium cations, the complex-forming ability increases with increase in the number of oxygen donor centers in the polyether chain of the ligand.Translated from Izvestiya Akademii Nauk SSSR, Seriya Khimicheskaya, No. 9, pp. 1990–1997, September, 1989.Previous communications, see [2, 3].     

Non-covalent interactions of alkali metal cations with singly charged tryptic peptides

The complexes formed by alkali metal cations (Cat(+) = Li(+), Na(+), K(+), Rb(+)) and singly charged tryptic peptides were investigated by combining results from the low-energy collision-induced dissociation (CID) and ion mobility experiments with molecular dynamics and density functional theory calculations. The structure and reactivity of [M + H + Cat](2+) tryptic peptides is greatly influenced by charge repulsion as well as the ability of the peptide to solvate charge points. Charge separation between fragment ions occurs upon dissociation, i.e. b ions tend to be alkali metal cationised while y ions are protonated, suggesting the location of the cation towards the peptide N-terminus. The low-energy dissociation channels were found to be strongly dependant on the cation size. Complexes containing smaller cations (Li(+) or Na(+)) dissociate predominantly by sequence-specific cleavages, whereas the main process for complexes containing larger cations (Rb(+)) is cation expulsion and formation of [M + H](+). The obtained structural data might suggest a relationship between the peptide primary structure and the nature of the cation coordination shell. Peptides with a significant number of side chain carbonyl oxygens provide good charge solvation without the need for involving peptide bond carbonyl groups and thus forming a tight globular structure. However, due to the lack of the conformational flexibility which would allow effective solvation of both charges (the cation and the proton) peptides with seven or less amino acids are unable to form sufficiently abundant [M + H + Cat](2+) ion. Finally, the fact that [M + H + Cat](2+) peptides dissociate similarly as [M + H](+) (via sequence-specific cleavages, however, with the additional formation of alkali metal cationised b ions) offers a way for generating the low-energy CID spectra of 'singly charged' tryptic peptides.     

Inverse selectivity series for the adsorption of alkali metal cations on the side walls of laminar aluminosilicate crystals

An inverse selectivity was found for the adsorption of alkali metal cations on the side walls of montmorillonite and kaolinite crystals. The results are in accord with the data for the adsorption of alkali metal cations on silica gel at neutral and high pH and on alumina and hematite at pH values above their isoelectric points. The existence of a direct or inverse selectivity series for these cations depends on the concentration of exchange sites on the surface of mineral ion exchange materials and the contribution of the energy of the electrostatic repulsion between adjacent cations to the total energy of their adsorption on the ion exchange materials. A. V. Dumanskii Institute of Colloid Chemistry and Water Chemistry, National Academy of Sciences of Ukraine, 42 Akademika Vernadskogo Prosp., Kiev-142, Ukraine 252680. Translated from Teoreticheskaya i éksperimental’naya Khimiya, Vol. 34, No. 1, pp. 32–35, January–February, 1998.     

Tetraphenylborate salts of alkali and alkaline earth metal complex cations

An introductory review summarises complex formation between poly(alkyleneoxy) adducts and inorganic salts. This is followed by preparative and IR and NMR spectroscopic features of the tetraphenylborates of complexes of polyethylene glycols, nonylphenoxy(polyethyleneoxy)ethanols and polypropylene glycols with sodium, magnesium, calcium, strontium and barium ions. Generally, an alkylene oxide:cation ratio of 8.5:1 is indicated for the complexes with sodium, and 12:1 (∼10.5:1 for the polyethylene glycols)_for the complexes with the alkaline earth metals.