Ion and lithium isotope selectivity of monoclinic antimonic acid

Antimonic acid with the monoclinic structure, M-SbA, which had a high selectivity for the lithium ion among alkali metal ions, was prepared by extracting lithium ions from LiSbO₃ through ion exchange with protons and its lithium isotope selectivity has been studied. M-SbA underwent the reversible monoclinic-orthorhombic structural change upon desorption-sorption of lithium ions while it showed the irreversible monoclinic-cubic structural change upon sorption of sodium ions. Isotopically, M-SbA was a ⁶Li-specific ion exchanger. The ⁷Li-to-⁶Li isotopic separation factor was slightly dependent on the kinds of counterion in the solution phase of the batch experiments and the maximum S value obtained at 25°C was 1.025.     

Fragmentation reactions in the mass spectrometry analysis of neutral oligosaccharides.

A method is described to obtain multicollision dissociation threshold (MCDT) values. These values provide relative reaction thresholds for dissociation in the three major gas-phase fragmentation reactions of oligosaccharides complexed to alkali metal ions. The quasimolecular ions are produced using matrix-assisted laser desorption/ionization Fourier transform mass spectrometry. The MCDTs for alkali metal ion dissociation and glycosidic bond and cross-ring cleavages were resolved from the kinetic energy dependence of collision-induced dissociation (CID) products. The relative strengths of alkali metal ion binding to N,N'-diacetylchitobiose (chitobiose) and N,N',N"-triacetylchitotriose (chitotriose) were probed using sustained off-resonance irradiation (SORI) CID. Experiments to evaluate MCDT values and the method for obtaining them were performed by studying alkali metal ion coordinated crown ethers. Molecular dynamic simulations were also performed to provide insight into the alkali metal ion binding of chitin-based oligosaccharides. The relative dissociation thresholds of glycosidic bond cleavages and cross-ring cleavages were determined for various alkali metal ion coordinated oligosaccharides. The activation barriers of glycosidic bond cleavages were found to depend on the size of the alkali metal ion. Cross-ring cleavages were found to be independent of the alkali metal ion but dependent on linkage type. The results suggest that glycosidic bond cleavages are charge-induced while cross-ring cleavages are charge-remote processes.     

Plasmonic-coupling-based sensing by the assembly and disassembly of dipycolylamine-tagged gold nanoparticles induced by complexing with cations and anions

A surface-plasmon-coupling-mediated sensor system is developed based on Au nanoparticles tagged with a coordinative dipycolylamine and lipoyl-anchored naphthalimide derivative (AuNP@DPA). The AuNPs with tailored ligands exhibit distinct sensing activity via sequential assembly into nanoparticle aggregates induced by metal ion complexing, and disassembly in the presence of pyrophosphate (PPi) anions, which is accompanied by a swift, reversible color change due to a surface plasmon resonance coupling effect. It is found that divalent metal ions are more effective than mono- or tri-valent ions in the aggregate formation process, Mn(2+)-induced aggregates are more sensitive to the capture of PPi anions than other AuNP aggregates, and the disassembly upon anion complexation exhibits a highly selective response. The AuNP@DPA-based molecular recognition system also demonstrates a viable performance for the detection of total selective metal ions present in different types of water analytes.     

An equilibrium partitioning model for predicting response to host-guest complexation in electrospray ionization mass spectrometry

While electrospray ionization mass spectrometry (ESI-MS) has become a powerful technique for analyzing many types of host-guest complexation, questions remain as to just how accurately ion abundances generated by ESI reflect the true distribution of species at equilibrium in solution. To better understand this relationship, an equilibrium partitioning model was developed to explain the various interactions that dictate how much of a particular host-guest complex is transferred from solution into the gas phase in the ESI process. By evaluating the simultaneous equilibria of the complexation reaction and the partitioning of species between the surface and interior of the ESI droplets, one can estimate the ion abundances generated. The predictions of this new model were evaluated and experimentally confirmed through the analysis of the complexes of 18-crown-6 with alkali metal cations in an ESI quadrupole ion trap mass spectrometer, and it was determined that binding constants alone may not give accurate predictions about the observed ESI-MS response to different host-guest complexes.     

Effect of metal ions on the molecular weight distribution of humic substances derived from municipal compost: ultrafiltration and size exclusion chromatography with spectrophotometric and inductively coupled plasma-MS detection

The effect of metal ions (Co, Cu, Ni, Pb, Zn) on the molecular weight distribution of humic substances (HSs) obtained from compost is studied. We believe this is the first of this type of study applied in this way to humic substances. Size exclusion chromatography is coupled with two on-line detection systems (spectrophotometric and ICPMS) to study the binding of metal ions by humic substances leached from compost. ICPMS provided highly specific, sensitive, and multielement analytical information that enabled obtaining direct experimental evidence for the participation of metal ions in molecular size distributions of humic compounds. The compost extract or its high molecular weight fraction (>5,000) was put in contact with EDTA or citrate ions, thereby competing with HSs for binding metals. The experiments were carried out by varying the pH maintained by Tris-HCl or CAPS buffer (pH 8.0 and 10.3) and keeping the ionic strength constant. The elution profile of humic substances using UV/ visible detection was compared with those from ICPMS detection of Co, Cu, Ni, Pb, and Zn in the same chromatographic runs. The results obtained suggested that both bridging between small molecules and complexation/ chelation by individual molecules are involved in metal ion binding to humic substances. The use of ICPMS to study the role of metal ions in aggregation/disassociation of humic substances proposed in this work is promising. Coupling element-specific detection with SEC or other separation systems allows better understanding of the mobility and bioaccessibility of elemental species in the environment and further elucidation of the dissolved humic structure.     

New polymer-supported ion-complexing agents: design, preparation and metal ion affinities of immobilized ligands

Polymer-supported reagents are comprised of crosslinked polymer networks that have been modified with ligands capable of selective metal ion complexation. Applications of these polymers are in environmental remediation, ion chromatography, sensor technology, and hydrometallurgy. Bifunctional polymers with diphosphonate/sulfonate ligands have a high selectivity for actinide ions. The distribution coefficient for the uranyl ion from 1 M nitric acid is 70,000, compared to 900 for the monophosphonate/sulfonate polymer and 200 for the sulfonic acid ion-exchange resin. A bifunctional trihexyl/triethylammonium polymer has a high affinity and selectivity for pertechnetate and perchlorate anions from groundwater. In one example, its distribution coefficient for perchlorate ions in the presence of competing anions is 3,300,000, compared to 203,180 for a commercially available anion-exchange resin. Polystyrene modified with N-methyl-D-glucamine ligands is capable of selectively complexing arsenate from groundwater. It complexes 99% of the arsenate present in a solution of 100 mg/L arsenate with 560 mg/L sulfate ions. Its selectivity is retained even in the presence of 400 mg/L phosphate. There is no affinity for arsenate above pH 9, allowing for the polymer to be regenerated with moderate alkali solution. In studies aimed at developing a Hg(II)-selective resin, simple amine resins were found to have a high Hg(II) affinity and that affinity is dependent upon the solution pH and the counterion.     

Voltage-Controlled Fluorometry of the Transfer of Nonfluorescent Ions across the 1,2-Dichloroethane/Water Interface Using Fluorescent Ionophores

The voltage-driven transfer of alkali and alkaline-earth metal ions across the polarized 1,2-dichloroethane (DCE)/water interface has been measured fluorometrically by using two fluorescent ionophores, coumarin 153-linked monoaza-15-crown-5 (C153-crown(O(4))) and two-coumarin 153-linked diaza-18-crown-6 ((C153)(2)-K(22)). The 1:1 complex formation prevails for both monovalent and divalent ion transfer, when the concentration of C153-crown(O(4)) in DCE is at the micromolar level. In the Mg(2+) ion transfer, the formation of the 1:2 (metal-ligand) complex becomes significant at the millimolar level of C153-crown(O(4)). C153-crown(O(4)) seems to adsorb at the interface. The complexation of Ba(2+) with (C153)(2)-K(22) is significantly slower than the complexation with C153-crown(O(4)).     

Composition and Architecture Design of Double‐Shelled Co0.85Se1−xSx@Carbon/Graphene Hollow Polyhedron with Superior Alkali (Li,Na, K)‐Ion Storage

The exploration of materials with reversible and stable electrochemical performance is crucial in energy storage, which can (de) intercalate all the alkali‐metal ions (Li⁺, Na⁺, and K⁺). Although transition‐metal chalcogenides are investigated continually, the design and controllable preparation of hierarchical nanostructure and subtle composite withstable properties are still great challenges. Herein, component‐optimal Co_0.85Se_1?xS_x nanoparticles are fabricated by in situ sulfidization of metal organic framework, which are wrapped by the S‐doped graphene, constructing a hollow polyhedron framework with double carbon shells (CoSSe@C/G). Benefiting from the synergistic effect of composition regulation and architecture design by S‐substitution, the electrochemical kinetic is enhanced by the boosted electrochemistry‐active sites, and the volume variation is mitigated by the designed structure, resulting in the advanced alkali‐ion storage performance. Thus, it delivers an outstanding reversible capacity of 636.2 mAh g^?1 at 2 A g^?1 after 1400 cycles for Li‐ion batteries. Remarkably, satisfactory initial charge capacities of 548.1 and 532.9 mAh g^?1 at 0.1 A g^?1 can be obtained for Na‐ion and K‐ion batteries, respectively. The prominent performance combined with the theory calculation confirms that the synergistic strategy can improve the alkali‐ion transportation and structure stability, providing an instructive guide for designing high‐performance anode materials for universal alkali‐ion storage.     

磁性金属有机复合材料的合成与应用

金属有机框架材料(MOFs)是一种将金属离子中心与有机配体通过配位键结合起来的一类具有网格结构的材料。由于金属离子以及有机配体的多样性,MOFs的结构也具有多样性。磁性金属有机复合材料是一种新型的复合材料,既结合了MOFs的网状结构及结构多变性的优点,又结合了磁性材料易于分离且可重复利用的特性,使得这种材料在药物载体、多相催化、选择吸附等多种方面都有着较为广泛的应用。以经典的几类MOFs为分类依据,研究了它们与磁性材料结合形成新型复合材料的方法,同时概括了这些新型复合材料在不同领域的应用,最后提出了该材料目前所存在的问题,并对今后的研究方向进行了展望。     

Conductivity problems in two dimensional intercalation compounds

The ionic conductivity of two dimensional alkali metal intercalation compounds depends on factors such as the ratio between the number of intercalated ions and available vacancies in the v.d.w. gap, the nature of the bonds in the host structure, the site geometry, the nature of the alcalin ion. The problems of the electrons lost by the alkali metal is discussed in light of new experimental results. A simple model assuming a delocalization in the conduction band of the host does not apply to all the systems. Two or more classes of intercalation compounds may exist.     

Silver ion-selective electrodes using pi-coordinate calix

Calix[4]arene derivatives incorporating pi-coordinate substituents such as allyl, benzyl, and propargyl groups were designed as soft neutral carriers for silver ion sensors. Most of all, tert-butylcalix[4]arene tetra(allyl ether) is an excellent neutral carrier for plasticized poly(vinyl chloride)-membrane silver ion-selective electrodes. The ion sensors showed high silver ion selectivity over alkali metal ions and also good selectivity against other soft metal ions such as lead and mercury(II) ions. The electrode potential response was as rapid as that for neutral-carrier-type alkali metal ion electrodes due to the soft interaction between pi-coordinate substituents and silver ion, which was elucidated by 1H NMR spectroscopy.     

Extended networks formed by coordination polymers in the solid state

Coordination polymers based upon the self-assembly of metal ions with bridging ligands often show fascinating extended network structures in the solid state. In principle, variation of the molecular components used in the construction of such networks (i.e. metal ion, bridging ligand, co-ligands and counter-anion) affords an almost limitless range of materials that, it is anticipated, will have interesting physical and electronic properties. Thus, linking different metal ions showing different stereochemical preferences with designed bridging-ligands of varying topology and connectivity means that many different network topologies can be accessed. The enormous number of variables associated with coordination network construction means that a ‘combinatorial chemical apporach’ is an appropriate methodology for screening product structures. As it can be difficult to control and predict the nature of the network polymer produced, current research continues to search for an understanding of how building-block design can be used to control extended network structure so that functional materials can be targeted specifically.     

Investigation of alkali metal migration and accumulation in the SiO2/Si system: Structure of the interface

An electrochemical method was applied to the determination of accumulation parameters of alkali metal ions in SiO₂ film as well as to detecting the specific features of the SiO₂---Si interface structure. The activation energies for accumulation of sodium, potassium and caesium in thermally grown films were determined. An assumption of the presence in the interface of a barrier layer to alkali metal ion movement was made.     

Inhomogeneous complexation of trace metals in water with organic nano-complexants

The complexation of heavy metals, such as Cd²⁺ and Ni²⁺, with organic complexants such as 1-(2-pyridylazo)-2-naphthol (PAN) and 1-(2-thiazolylazo)-2-naphthol (TAN) in water has been investigated. Under such conditions, both the reagents and the products form nano-particulates. These materials are important because their spectrum changes upon exposure to heavy metals and they may be used for design of new optical detectors. The kinetic schemes so far suggested for these complexation reactions are not valid for such experimental conditions, since they assume homogeneous behavior. We provide evidences to the inhomogeneous nature of these reactions. The complexation has been studied using TEM imaging, zeta-potentiometry, time-dependent particulate size analysis and time-dependent spectroscopy. Many of the experimental results are explained in terms of the nature of the nano-particulates of these two complexants. Several processes were identified, including crystal growing of the complexant, its reaction with metal ions in solution and on the surface area, chemical erosion of complexant crystallites and their decomposition, re-crystallization of the formed complexes and long term aggregation of both the complexant and the resulted complex. It was found that the needle-like nano-structures on the surface of the TAN particulates governs its reaction and particulate behavior. The known optimal complexation conditions, such as pH, and delay time are now understood in terms of the zeta-potential minima of the suspensions and in terms of the kinetic parameters. Also the interferences of some ions in the Ni–TAN complexation are now quantified and the kinetic data indicate the best delay time when the interfering effects are minimal.     

Metal salts for molecular ion yield enhancement in organic secondary ion mass spectrometry: a critical assessment

In a search for molecular ion signal enhancement in organic SIMS, the efficiency of a series of organic and inorganic salts for molecular cationization has been tested using a panel of nonvolatile molecules with very different chemical characteristics (leucine enkephalin, Irganox 1010, tetraphenylnaphthalene, polystyrene). The compounds used for cationization include alkali bromide and group Ib metal salts (XBr with X = Li, Na, K; CF3CO2Ag; AgNO3; [CH3COCH=C(O-)CH3]2Cu; AuCl3). Alkali ions, very good for polar molecule cationization, prove to be of limited interest for nonpolar molecules such as polystyrene. Silver trifluoroacetate displays excellent results for all the considered molecules, except for leucine enkephalin (which might be due to the use of different solvents for the analyte and the salt). Instead, silver nitrate mixed with leucine enkephalin in an ethanol solution provides intense molecular signals. The influence of the respective concentrations of analyte and salt in solution, of the silver trifluoroacetate solution stability, and of the sample microstructure on the secondary ion intensities are also investigated. The results of other combinations of analyte and salts are reported. Finally, the use of salts is critically compared to other sample preparation procedures previously proposed for SIMS analysis of large organic molecules.     

Kinetic aspects of Donnan membrane technique for measuring free trace cation concentration

Addition of ion complexation ligands in the acceptor solution in the Donnan membrane technique (DMT) can lower its detection limit for free metal ion concentration in natural samples. In this paper, the influence of added ligands on the transport behavior of trace ions in DMT was studied using numerical and analytical models and experimental tests. The results show that addition of ligands in the acceptor can significantly influence the time to reach the Donnan membrane equilibrium. Depending on several factors, the flux can be controlled by the diffusion in the stagnant solution film at the solution-membrane interface, by the diffusion in the membrane, or by both. The conditions under which the diffusion in the solution film or in the membrane becomes the rate-limiting step are discussed and approximate analytical solutions for some special cases are presented. Very low concentrations of free metal ion can be measured using the ligand complexation DMT. Depending on the degree of complexation in the sample, the measurement can be based on either the Donnan membrane equilibrium (when the complexation degree is low) or the kinetic interpretation of the ion transport (when the complexation degree is high).     

The effect of small cations on the positive electrospray responses of proteins at low pH

Solutions consisting of protein and small molecule mixtures have been subjected to electrospray ionization to study the influence of small molecule/cation components at high concentrations on the electrospray responses of proteins. Emphasis was placed on solutions consisting of equal parts methanol and water and containing 1 vol % acetic acid. The results, therefore, are relevant to low pH solutions with significant organic content, a commonly used set of conditions in electrospray ionization mass spectrometry that tends to denature proteins. A variety of small cations/molecules were selected to sample a range of chemical characteristics. For example, sodium and cesium cations were studied to represent metal ions, tetrabutylammonium and tetramethylammonium cations were studied to represent quaternary ammonium compounds with different surface activities, and octadecylamine and glycine were studied to represent species that compete for protons but have different surface activities. A methodology for measuring relative ion suppression efficiencies was developed and applied for protein ions derived from bovine cytochrome c. The form of the small cation (i.e., metal ion, quaternary ammonium ion, or protonated molecule) did not appear to be a factor in determining the efficiency with which protein ion signals were suppressed. The extent to which ions are expected to concentrate on the surface, however, was the major factor in determining the ion suppression efficiency. Itwas found that the ion suppression efficiency of the most surface active species in this study was comparable to that of a protein on another protein after normalization by charge. These results are particularly relevant to the development of mixture analysis strategies based on ionization and tandem mass spectrometry applied to mixtures of whole proteins.     

Solvation energy and gas-phase stability influences on alkali metal cluster ion formation in electrospray ionization mass spectrometry

The ability to observe abundant gas-phase metal cluster ions in electrospray ionization mass spectrometry (ESI-MS) is highly dependent on experimental conditions. Alkali halides (MX) and other alkali metal salts were used to investigate the formation of cluster ions in ESI-MS. All compounds were found to give cluster ions of the form (M(n)(+1)X(n))(+) and (M(n)X(n+1))(-), with only two alkali salts yielding doubly charged cluster ions. In homologous alkali halide series, the relative abundances of cluster ions increased with increasing size of either the cation (positive ion mode) or the anion (negative ion mode). Calculations using an electrostatic model show that the gas-phase stability of cluster ions is greater for smaller cations or anions when a fixed counterion is employed. This stability calculation goes in a direction just opposite to the trend in cluster ion abundances observed in ESI-MS. Studies of equimolar mixtures consisting of two alkali halides reveal two distinct trends. When the equimolar mixture was composed of differing ions that participate in the droplet charge excess with the same counterion, the less solvated ions were found to form more abundant cluster ions. When the ions participating in the charge excess were fixed, the preferred counterion in observed clusters was the one that is more solvated in solution and forms more stable clusters in the gas phase. These observations can be rationalized by an extended form of the charged residue model where the weakly solvated ions that are part of the charge excess are preferentially enriched in offspring droplets during uneven fission. By contrast, transfer of a particular counterion located in the bulk of the droplets to the offspring droplets is not disfavored when this counterion is strongly solvated.     

磷铝酸盐玻璃中铋离子近红外发光与光学碱度反常现象

研究了铋离子掺杂磷铝酸盐玻璃近红外发光与光学碱度的反常现象. 研究发现, 通过改变碱金属离子半径调节玻璃基质光学碱度, 在808 nm激光激发下铋离子位于1300 nm波段的近红外宽带发光强度随光学碱度的增大而增强, 而在690 nm激光激发下得到的1100 nm波段近红外发光强度则随着光学碱度的增大而减弱. 该玻璃1300 nm波段近红外发光强度与光学碱度依存关系与以往报道结果相反, 且也与1100 nm波段发光特性相反. 根据上述结果可以推测玻璃中1100和1300 nm波段的近红外发光源于不同价态的铋离子, 而该玻璃体系的基质结构自还原作用是导致上述现象产生的主要原因.     

UV-radiation curing of simultaneous interpenetrating polymer network hydrogels for enhanced heavy metal ion removal

Simultaneous interpenetrating polymer network (IPN) hydrogels have been prepared by UV-initiated polymerization of a mixture of acrylamide (AM) and triethylene glycol divinyl ether (DVE-3). The consumption of each monomer upon UV-irradiation was monitored in situ by real-time infrared (RTIR) spectroscopy. The acrylamide monomer AM was shown to polymerize faster and more extensively than the vinyl ether monomer DVE-3, which was further consumed upon storage of the sample in the dark, due to the living character of the cationic polymerization. The IPN hydrogels were used to remove heavy metal ions from aqueous solution under the non-competitive condition. The effects of pH values of the feed solution and the DVE-3 content in the formulation on the adsorption capacity were investigated. The results indicated that the adsorption capacity of the IPN hydrogels increased with the pH values and DVE-3 content in the formulation. Furthermore, the synergistic complexation of metal ions with two polymer networks in the IPN was found in the adsorption studies. Adsorption kinetics and regeneration studies suggested that the IPN hydrogels could be used as fast-responsive and renewable sorbent materials in heavy metal removing processes.