Dicarboxylate Anions Research Articles

From 1D to 2D coordination polymers based on benzimidazole and dicarboxylate: Syntheses, structures, and fluorescence properties

Three new Zn(II)/Cd(II) coordination polymers (CPs), {[Zn(4pybbp)(fumarate)0.5(NO3)]·(DMA)2·(H2O)2.25}n (1), {[Zn(4pybbp)(glutarate)]·H2O}n (2), [Cd(4pybbp)(isophthalate)]n (3) (4pybbp = 2-(6-(1H-Benzo[d]imidazole-2-yl)pyridine-2-yl)-1-(pyridine-4-methylpyridine-1H-benzo[d]imidazole; DMA = dimethylacetamide) have been prepared using solvothermal method by introducing different dicarboxylate anion. Single crystal analysis shows that CP 1 and 2 are one-dimensional (1D) trapezoidal double-stranded and linear single-stranded structures, respectively, while CP 3 is two-dimensional (2D) planar structure. The structural disparities among the three coordination polymers can be ascribed to the size of d10 metal ions and the coordination mode of ligands. The solid-state fluorescence properties indicate that the fluorescence peaks of the coordination polymers 1–3 belong to the π*-π transition of the ligand 4pybbp, which occur significant blue-shift and enhancement. The order of fluorescence blue-shift is 1 > 2 > 3, which is consistent with the bond length order of Zn/Cd-Npyridine. The stronger fluorescence of the CPs than the ligand is due to the immobilization of the ligand through coordination, which reduces the energy loss of thermal vibration. Moreover, the fluorescence intensity of coordination polymers increases with the skeleton structure from 1D to 2D. Therefore, coordination and skeleton structure will affect the fluorescence of the coordination polymers.

Elucidating effect of dicarboxylate anions on nanostructural organization of dicationic imidazolium-based ionic liquids

This work reports the influence of the dicarboxylate anion (oxalate, malonate succinate, glutarate, adipate, pimelate) on the aggregation process of ionic liquids derived from 1,8-bis(3-methylimidazolium-1-yl)-octane [C8(MIM)2] and 1,10-bis(3-methylimidazolium-1-yl)-decano [C10(MIM)2] in water solution. The aggregation behavior was investigated using electrical conductivity, nuclear magnetic resonance, transmission electron microscopy, atomic force microscopy, and zeta potential. Results showed that the aggregates have a wormlike morphology. The CAC values for [C10(MIM)2]2+ increase in the following order: [Oxa] < [Suc] < [Mal] < [Glu] < [Adi] < [Pim], which indicates a direct relationship with the increase in the number of methylene groups of the dianion spacer. In the case of [C8(MIM)2]2+, there was no relationship between the CAC value and the anion’s alkyl spacer chain length, which was attributed to the flexibility and complexity of the dynamic behavior of the aggregates. Anions on the nanorganized structures of micelles are oriented in the way that carboxylate groups are at the aggregate surface (forming hydrogen bonds with cationic heads and water), and apolar alkyl chains are in the hydrophobic (downshift) region of the micelles making an arrangement where they also adopt the bend conformation of alkyl chains. The aggregation of dicationic ILs with dicarboxylate anions is a very innovative topic of investigation in the literature, and more research on different structures, system conditions, and techniques could be done to gain a better understanding of these systems.

Two Zn(II) complexes based on bis(benzimidazole) and different dicarboxylate anions: synthesis, structures, and fluorescent properties

Two new zinc(II) complexes, [Zn2(PBM)2(terephthalate)(formate)2] (1) and {[Zn(PBM)(fumarate)]∙H2O}n (2), were synthesized using 1,3-bis(1H-benzo[d]imidazol-2-yl)propane (PBM) and two different dicarboxylic acids under solvothermal conditions. Complexes 1 and 2 have been characterized by infrared spectroscopy, elemental analysis, and single-crystal X-ray diffraction analysis. The structural analysis showed that 1 was a binuclear structure and then formed a 3D supramolecular network structure through hydrogen bond and π-π conjugation, while 2 was a one-dimensional coordination polymer. In 1 and 2, the zinc ions were four-coordinate with an N2O2 donor set and a slightly distorted tetrahedral geometry. The solid-state fluorescence properties indicate that the fluorescence peaks belong to the π*-π transition of the ligand PBM, which has a significant red shift and enhancement with the order being 1 > 2 > PBM. The stronger fluorescence of the complexes than the ligand is due to the immobilization of the ligand through coordination, which reduces the energy loss of thermal vibration. The π∙∙∙π conjugation in 1 results in a stronger fluorescence of 1 than 2. Therefore, coordination and π∙∙∙π conjugation will affect the fluorescence of complexes.

Thermodynamic studies on the formation of ion-pair cobalt complexes in acetone–water mixtures

Dicarboxylic acids are stronoger acids than moncraboxylic acids and more soluble in water due to the presence of two carboxylic (–COOH) groups which are industrially important in producing polyester, polyamides, and polyols and as a pioneer to pharmaceutical additives. Succinic acid is one of the most prosperous chemicals that can be generated from renewable resources which can be used in the industries of antiseptics, cosmetics, sutures, drugs, solvents, detergents, herbicides, fungicides, synthetic resins, and inks. The ion–pair formation is very important in diferent applications, used widely for inorganic analysis by liquid chromatography and used for the heavy metal removal from waste water, so studing the ion-pair association constant (KA) formed between chloropentamminecobalt(III) cation [CpX2+] and a different ligands of dicarboxylate anions (AC2-), have been determined by EMF technique in different compositions of acetone aqueous media (0–44.20 wt% acetone) for succinic acid and for the other dicarboxylic acids (Maleic, Malonic and Malic) in the same solvent composition (40 wt% acetone) with in temperature range (30 – 60 °C). The thermodynamic association properties (ΔGA°, ΔHA° and ΔSA°) have been estimated and discussed. Extra thermodynamic correlations like ΔHA°- ΔSA° and ΔGA°- ΔGI(orII)° (where I and II are mentioned for the first and second dissociation constant of the dicarboxylic acids) in different compositions of acetone aqueous media for succinic acid and in fixed solvent composition for the other dicarboxylic acids were examined in order to give more information about the behavior of solvent molecules and its effect on formation of the ion-pair molecules. In addition, The Gibbs free energy of transfer for the association process ΔGA°(t) from water to acetone mixed solvents were calculated for succinic acid in order to indicate the spontaneous nature and the stabilization of the ion-pair by increasing the acetone weight percent in the mixed acetone – aqueous media. The linear correlation between pKD values and the relative permittivity of acetone aqueous medium is in accordance to Born’s equation.

Effective guest uptake and release using an azobenzene-embedded molecular cage

Designing cages with switchable cavities towards guests is the key for effective drug loading and controlled release. For this purpose, a new asymmetrical molecular cage containing two aza-vertices and three linkers-one azobenzene group and two diphenyl ether units—was synthesized. After complexing with two copper ions onto the vertices, the formed di-metallic cage shows a strong binding affinity (Ka = 1.58 × 107 M−1) towards a rhodamine dicarboxylate anion and can capture 79% of the guest in CH3CN/H2O solution even at extremely low concentrations of both 1.0 × 10−6 M. Furthermore, owing to high E→Z photoisomerization efficiency of the embedded azobenzene unit, 84% of the loaded rhodamine guest would be released from the cage cavity by UV light irradiation.

Thermochemical CO2 Reduction Catalyzed by Homometallic and Heterometallic Nanoparticles Generated from the Thermolysis of Supramolecularly Assembled Porous Metal-Adenine Precursors.

A family of unprecedented supramolecularly assembled porous metal-organic compounds (SMOFs), based on [Cu6M(μ-adeninato)6(μ3-OH)6(μ-H2O)6]2+ cations (MII: Cu, Co, Ni, and Zn) and different dicarboxylate anions (fumarate, benzoate, and naphthalene-2,6-dicarboxylate), have been employed as precursors of catalysts for the thermocatalytic reduction of CO2. The selected metal-organic cation allows us to tune the composition of the SMOFs and, therefore, the features and performance of the final homometallic and bimetallic catalysts. These catalysts were obtained by thermolysis at 600 °C under a N2 atmosphere and consist of big metal particles (10-20 μm) placed on the surface of the carbonaceous matrix and very tiny metal aggregates (<10 nm) within this carbonaceous matrix. The latter are the most active catalytic sites for the CO2 thermocatalytic reduction. The amount of this carbonaceous matrix correlates with the organic content present in the metal-organic precursor. In this sense, CO2 thermocatalytic reduction experiments performed over the homometallic, copper only, catalysts with different carbon contents indicate that above a certain value, the increase of the carbonaceous matrix reduces the overall performance by encapsulating the nanoparticles within this matrix and isolating them from interacting with CO2. In fact, the best performing homometallic catalyst is that obtained from the precursor containing a small fumarate counterion. On the other hand, the structural features of these precursors also provide a facile route to work with a solid solution of nanoparticles as many of these metal-organic compounds can replace up to 1/7 of the copper atoms by zinc, cobalt, or nickel. Among these heterometallic catalysts, the best performing one is that of copper and zinc, which provides the higher conversion and selectivity toward CO. XPS spectroscopy and EDX mappings of the latter catalyst clearly indicate the presence of Cu1-xZnx nanoparticles covered by small ZnO aggregates that provide a better CO2 adsorption and easier CO release sites.

Ultracycles consisting of macrocycles

Presented here is a one-pot strategy starting from rationally designed macrocyclic precursors for the diverse construction of sophisticated ultracycles. The type and amount of the base were found to significantly influence the macrocyclization outcome. The use of 4.0 equiv. CsF resulted in ultracycles of both types A and B while the presence of CsF larger than 6.0 equiv. produced only type B ultracycles. Existence of anion template increased the total yields and affected the distribution of the ultracycles. The ultracycles can accommodate large organic dicarboxylates anions via multiple anion–π and hydrogen bonds, and show selectivity to the size-matched heptanedioate (C72−). Based on all possible species and relevant equilibrium constants as well as material and charge balances, a numerical iterative algorithm was developed and applied to fit the association constants of B2H with dicarboxylates from glutarate (C52−) to octanedioate (C82−), which gave association constants up to 103 L/mol.

An Electrochemical and Spectroscopic Characterization of Chiral MIL-53(Fe) Metal-Organic Framework

Metal-organic frameworks (MOFs) have attracted increasing scientific interest due to unique features including high specific surface areas, exceptional porosity, high crystallinity and tuneable pore size [1]. In fact, the opportunity to achieve porous materials with high modularity and diverse functionality make MOFs suitable candidate for solid-state materials. In recent years, scientists conducted intense research in the production of chiral MOFs (CMOFs). The attractiveness of chiral MOFs is due to their specific application including chiral enantioselective recognition, enantioselective separation, asymmetric catalysis, and sensing. Chirality within MOFs can occur in each of the components, whether linker, metal node, or even guest molecules [2]. MIL-53(Fe) is the most common iron-based MOF. This class of compound is obtained by a combination between iron(III) cations and 1,4-dicarboxylic acid consists of three-dimensional networks which contain FeO6 hexagonal chains and dicarboxylate anions. MIL-53(Fe) shows significant advantages compared with other MOFs, which include chemical stability, the presence of nontoxic and widely available metals [3]. MIL-53(Fe) derivatives containing chiral molecules (cysteine and camphorsulfonic acid) were characterized by IR, XRD and Electron Spectroscopy. The electrochemical behaviour of the synthesized MOFs was characterized on solid state using a glassy carbon (GC) electrode and by making a paste with graphite powder. Cyclic voltammetry (CV) measurements show different redox behaviour depending on the type of molecules present inside the framework. The experimental results were integrated and related to the properties obtained using DFT based quantum mechanical calculations.

An amphiphilic macrocyclic acylhydrazone dimer: Facile synthesis and dual channel detection and removal of phthalate anion

Despite the large number of dicarboxylates’ receptors, the dual channel ones capable of recognizing and removing of phthalate anion are rare and the task remains challenging. In this paper, a facilely synthesized amphiphilic macrocyclic acylhydrazone dimer (AMAD) can not only detect phthalate anion selectively, through both color changes and turn-on fluorescence in solution as well as in solid state, but is also able to remove it from either water or organic solvents. The current study paves the way for the search of more multiple functional receptors of dicarboxylates anions.

Protein-induced modifications in crystal morphology of a hydrogen-bonded organic framework

In this work, we studied the encapsulation of a range of proteins in a hydrogen-bonded organic framework (HOF) comprised of a tetraamidinium cation and diazobenzene-based dicarboxylate anion.

Selective binding of oxalate by a tris-ureido calix[6]tube in a protic environment.

Due to their significant role in industry and biological systems, the interest in selectively recognizing and detecting small dicarboxylates has grown in recent years. In this study, we report on the binding properties of a family of tubular-shaped heterotritopic receptors based on bis-calix[6]arenes, which contain three (thio)urea bridges (C3U and C3TU) or six urea bridges (C6U), toward dicarboxylates. While poor binding properties were observed by NMR for the newly synthesized C6U, receptors C3U and C3TU exhibited a unique ability to cooperatively complex a dicarboxylate anion sandwiched between two ammonium ions. The three ions are complexed in contact and aligned within the tubular shape of the receptor, forming cascade complexes that are stable even in a competitive environment. The different binding properties between the receptors were rationalized in terms of size, flexibility, H-bond donor ability, and intramolecular H-bonding within the anion binding pocket between the calixarene cavities. With C3U, a rare selectivity for oxalate over other small dicarboxylates and various bicharged anions was observed. Molecular modeling of the cascade complex indicated that the oxalate anion is stabilized by an array of hydrogen bonds with the urea bridges of the receptor and both propylammonium cations nested within the calixarene cavities.

Supported Imidazolium-Based Ionic Liquids on a Polysulfone Matrix for Enhanced CO2 Capture.

The present work demonstrates the potential for improved CO2 capture capabilities of ionic liquids (ILs) by supporting them on a polysulfone polymeric matrix. CO2 is one of the main gases responsible for the greenhouse effect and is a focus of The European Commission, which committed to diminishing its emission to 55% by 2023. Various ILs based on combinations of 1-butyl-3-methyl- imidazolium cations and different anions (BMI·X) were synthesized and supported on a polysulfone porous membrane. The influence of the membrane structure and the nature of ILs on the CO2 capture abilities were investigated. It was found that the membrane's internal morphology and its surface characteristics influence its ILs sorption capacity and CO2 solubility. In most of the studied configurations, supporting ILs on porous structures increased their contact surface and gas adsorption compared to the bulk ILs. The phenomenon was strongly pronounced in the case of ILs of high viscosity, where supporting them on porous structures resulted in a CO2 solubility value increase of 10×. Finally, the highest CO2 solubility value (0.24 molCO2/molIL) was obtained with membranes bearing supported ILs containing dicarboxylate anion (BMI.MAL).

Neodymium-based metal-organic framework as an efficient catalyst for green synthesis of benzylidene-2-phenylhydrazine analogues

Neodymium-based metal-organic framework (Nd-MOF) has been prepared as an efficient heterogeneous catalyst in the click synthesis of benzylidine-2-phenylhydrazine analogs for the first time. In the presence of Nd-MOF, the reaction proceeds with mild conditions and a comparable yield has been achieved with less reaction time. In order to synthesize the [Nd(NDC) 1.5 (DMF)(H 2 O) 0.5 .0.5DMF] n , neodymium is used as a metal node to act as a cation and naphthalene-2,6-dicarboxylic acid as a well-extended organic linker as a dicarboxylate anion for building good coordinated 3D polymer. The synthesized Nd-MOF nanocatalyst was characterized by Powder XRD, BET, TGA, FT-IR, SEM-EDX, and TEM. Finally, the obtained products were examined through 1 H NMR, 13 C NMR, 15 N NMR and FT-IR. The nanocatalyst was completely recyclable and reusable for ten cycles without any loss of catalytic efficiency. Further, the nanocatalyst shows a crucial role in reducing the reaction time under mild experimental conditions. Additionally, the target molecules were afforded simple handling, eco-friendly and excellent yields with maximum efficiency.

A Charge-Neutral Self-Assembled L2Zn2 Helicate as Bench-Stable Receptor for Anion Recognition at Nanomolar Concentration.

The field of anion recognition chemistry is dominated by two fundamental approaches to design receptors. One relies on the formation of covalent bonds resulting in organic and often neutral host species, while the other one utilizes metal-driven self-assembly for the formation of charged receptors with well-defined nanocavities. Yet, the combination of their individual advantages in the form of charge-neutral metal-assembled bench-stable anion receptors is severely lacking. Herein, we present a fluorescent and uncharged double-stranded hydroxyquinoline-based zinc(II) helicate with the ability to bind environmentally relevant dicarboxylate anions with high fidelity in dimethyl sulfoxide (DMSO) at nanomolar concentrations. These dianions are pinned between zinc(II) centers with binding constants up to 145 000 000 M-1. The presented investigation exemplifies a pathway to bridge the two design approaches and combine their strength in one structural motif as an efficient anion receptor.

Unique Dimerization Topology and Countercation Binding Modes in 12‐Metallacrown‐4 Compounds

AbstractSeven dimeric metallacrowns (MC) based on Ln[12‐MCM(III)N(shi)‐4], where LnIII=Dy, Ho, Yb, or Y, MIII=Mn or Ga, and shi3− is salicylhydroximate, have been synthesized and characterized by single‐crystal X‐ray diffraction, and for the dysprosium‐manganese dimers, the magnetic properties have been measured. In each dimer two Ln[12‐MCM(III)N(shi)‐4] units are linked by four bridging dicarboxylate anions (isophthalate, trimesate, dinicotinate, or 2,2′‐dithiodibenzoate). Three different countercations (sodium, gallium(III), or pyridinium) were used to maintain charge balance of the dimer. While pyridinium does not bind to the dimer, the choice of the dicarboxylate dictates where the countercations Na+ or GaIII bind. With isophthalate and trimesate, the sodium ion binds to the central MC cavity opposite of the LnIII, and with dinicotinate the sodium or gallium(III) ions bind to the pyridyl nitrogen of the dinicotinate. All three Dy2Mn8 dimers exhibit an out‐of‐phase magnetic susceptibility signal consistent with a shallow barrier to magnetization relaxation.

Functional roles of ALMT-type anion channels in malate-induced stomatal closure in tomato and Arabidopsis.

Guard-cell-type aluminium-activated malate transporters (ALMTs) are involved in stomatal closure by exporting anions from guard cells. However, their physiological and electrophysiological functions are yet to be explored. Here, we analysed the physiological and electrophysiological properties of the ALMT channels in Arabidopsis and tomato (Solanum lycopersicum). SlALMT11 was specifically expressed in tomato guard cells. External malate-induced stomatal closure was impaired in ALMT-suppressed lines of tomato and Arabidopsis, although abscisic acid did not influence the stomatal response in SlALMT11-knock-down tomato lines. Electrophysiological analyses in Xenopus oocytes showed that SlALMT11 and AtALMT12/QUAC1 exhibited characteristic bell-shaped current-voltage patterns dependent on extracellular malate, fumarate, and citrate. Both ALMTs could transport malate, fumarate, and succinate, but not citrate, suggesting that the guard-cell-type ALMTs are dicarboxylic anion channels activated by extracellular organic acids. The truncation of acidic amino acids, Asp or Glu, from the C-terminal end of SlALMT11 or AtALMT12/QUAC1 led to the disappearance of the bell-shaped current-voltage patterns. Our findings establish that malate-activated stomatal closure is mediated by guard-cell-type ALMT channels that require an acidic amino acid in the C-terminus as a candidate voltage sensor in both tomato and Arabidopsis.

Fluorescent Supramolecular Organic Frameworks Constructed by Amidinium-Carboxylate Salt Bridges.

We report here a set of fluorescent supramolecular organic frameworks (SOFs) that incorporate aggregation-induced emission (AIE) units within their frameworks. The fluorescent SOFs of this study were constructed by linking the tetraphenylethylene (TPE)-based tetra(amidinium) cation TPE4+ and aromatic dicarboxylate anions through amidinium-carboxylate salt bridges. The resulting self-assembled structures are characterized by fluorescence quantum yields in the range of 4.6∼14 %. This emissive behavior is ascribed to a combination of electrostatic interactions and hydrogen bonds that operate in concert to impede motions that would otherwise lead to excited state energy dissipation. Single-crystal X-ray diffraction analyses revealed that the length of the dicarboxylate anion bridges has a considerable impact on the structural features of the resulting frameworks. Nevertheless, all SOFs prepared in the context of the present study were found to display emissive features characteristic of TPE-based AIE luminogens with only a modest dependence on the structural specifics being seen. The SOFs reported here could be reversibly "broken up" and "reformed" in response to acid/base stimuli. This reversible structural behavior is consistent with their SOF nature.

Antimicrobial and Toxicity Evaluation of Imidazolium-Based Dicationic Ionic Liquids with Dicarboxylate Anions.

Imidazolium-based dicationic ILs (DILs) presenting antimicrobial activity and relatively low toxicity are highly desirable and are envisioned for use in live tissue to prevent bacterial or fungal infections. In this context, we present here DILs with dicarboxylate anions [Cn(MIM)2[Cn(MIM)2][CO2-(CH2)mCO2], in which n = 4, 6, 8, and 10, and m = 0, 1, 2, 3, 4, and 5. The results showed that DILs with an alkyl chain spacer of ten carbons were active against yeasts and the bacterial strains tested. However, most of the DILs were cytotoxic and toxic at 1 mM. By contrast, DILs with alkyl chains possessing less than ten carbons were active against some specific Candidas and bacteria (mainly S. aureus), and they showed moderate cytotoxicity. The best activity against Gram-positive bacteria was observed for [C4(MIM)2][Pim] toward MRSA. For the DILs described herein, their level of toxicity against C. elegans was lower than that of most of the mono- and dicationic IL analogs with other anions. Our results showed that the presence of carboxylate anions reduces the toxicity of DILs compared to DILs containing halide anions, which is particularly significant to the means of designing biologically active compounds in antimicrobial formulations.

Temperature dependence of desolvation effects in hydrogen-bonded spin crossover complexes.

The synthesis, crystal structure and (photo)magnetic properties of the anhydrous spin crossover salt of formula [Fe(bpp)2](C6H8O4) (1) (bpp = 2,6-bis(pyrazol-3-yl)pyridine; C6H8O4 = adipate dianion), obtained by desolvation at 400 K of the original tetrahydrate in a single-crystal-to-single-crystal (SC-SC) transformation, are reported. This work offers a comparison between this compound and the previously reported hydrated material ([Fe(bpp)2](C6H8O4)·4H2O, 1·4H2O), highlighting the significance of the thermal conditions used in the dehydration-rehydration processes. In both compounds, a hydrogen-bonded network between iron(ii) complexes and adipate anions is observed. The original tetrahydrate (1·4H2O) is low-spin and desolvation at 450 K triggers a low-spin (LS) to high-spin (HS) transition to an amorphous phase that remains stable over the whole temperature range of study. Surprisingly, the dehydrated compound at 400 K (1) keeps the crystallinity, undergoes a partial spin crossover (T1/2 = 180 K) and a quantitative LS to HS photomagnetic conversion at low temperatures, with a T(LIESST) value of 61 K.

Nanoscale Forces between Basal Mica Surfaces in Dicarboxylic Acid Solutions: Implications for Clay Aggregation in the Presence of Soluble Organic Acids.

The stability of organomineral aggregates in soils has a key influence on nutrient cycling, erosion, and soil productivity. Both clay minerals with distinct basal and edge surfaces and organic molecules with reactive functional groups offer rich bonding environments. While clay edges often promote strong inner-sphere bonding of −COOH-laden organics, we explore typically weaker, outer-sphere bonding of such molecules onto basal planes and its significance in organomineral interactions. In this surface force apparatus study, we probed face-specific interactions of negatively charged mica basal surfaces in solutions containing carboxyl-bearing, low-molecular-weight dicarboxylic acids (DAs). Our experiments provide distance-resolved, nanometer-range measurements of forces acting between two (001) mica surfaces and simultaneously probe DA adsorption. We show that background inorganic ions display crucial importance in nanoscale forces acting between basal mica surfaces and in DA adsorption: Na+ contributes to strong repulsion and little binding of dicarboxylic anions, while small amounts of Ca2+ are sufficient to screen the basal surface charge of mica, facilitate strong adhesion, and enhance dicarboxylic anion adsorption by acting as cationic bridges. Despite reversible and weak adsorption of DAs, we resolve their multilayer binding via assembly of hydrophobic chains in the presence of Ca2+, pointing the importance of abundant, less reactive basal clay surfaces in organomineral interactions.