A Co(II)-Organic Coordination Polymer and Its Hydroxyl Multiwalled Carbon Nanotube Composite Incorporating 2-Iodo-4-sulfobenzoate Exhibiting Dual Electrochemical Sensing Performance for NO2- and Fe3

The novel Co(II) coordination polymer incorporating 2-iodo-4-sulfobenzoic acid (H2isba) and a pliable 1,4-bis(benzimidazole-1-methyl) benzene (bdbmb) ligand, {[Co(bdbmb)(H2O)4]·isba·2H2O·2DMA}n (Co(II)-CP), was synthesized. In addition, the composite of Co(II)-CP with the short hydroxyl multiwalled carbon nanotubes (Co(II)-CP@HCNTs) was prepared via an in situ preparation strategy. Amperometric current response reveals that the glass carbon electrodes (GCEs) of Co(II)-CP and Co(II)-CP@HCNTs exhibit highly sensitive electrochemical sensing toward NO2- and Fe3+ in the corresponding electrolytes. Co(II)-CP@HCNTs demonstrate superior electrocatalytic performance toward NO2- oxidation and Fe3+reduction to Co(II)-CP. The sensing mechanisms for NO2- and Fe3+ were illustrated with Hirshfeld surface analysis and density of states calculations. Furthermore, this methodology was successfully implemented on a miniaturized screen-printed electrode (SPE) platform. Among the three tested electrodes, the Co(II)-CP@HCNT-modified SPEs exhibited superior sensing capabilities, showing response ranges of 0.002-20 mM for nitrite and 0.002-38 mM for ferric ions, respectively. The calculated detection limits reached 0.12 μM for NO2- (δ = 0.00396 μA, N = 10) and 0.30 μM for Fe3+ (δ = 0.00201 μA, N = 10). Moreover, Co(II)-CP@HCNTs/SPE was further validated through practical applications for the detection of both analytes in real-world samples in the respective electrolytes.

Post-Synthetic Modification of an Amino-Functionalized Metal-Organic Framework for Highly In Situ Luminescent Detection of Mercury (II)

A sulfur-containing metal-organic framework, donated as UiO-66-NSMe, was prepared by the post-synthetic modification (PSM) of UiO-66-NH2 with 2-(Methylthio)benzaldehyde, and the successful synthesis of PSM was confirmed by X-ray photoelectron spectroscopy (XPS), FT-IR and 1H NMR studies. According to the characteristics of mercury thiophilic, UiO-66-NSMe could be used as a luminescent sensor for Hg2+ detection with a high selectivity and sensitivity (Ksv = 2.5 × 104 M-1; LOD = 20 nM), which could be attributed to the coordination between sulfur sites and Hg2+ based on XPS results. In practical applications, UiO-66-NSMe yielded satisfactory recovery rates (ranging from 96.1% to 99.5%) when it was employed for detecting Hg2+ in spiked environmental samples. Furthermore, UiO-66-NSMe was successfully employed to detect mercury (II) residues with the in situ rapid nondestructive imaging in simulated fresh agricultural products. Thus, this PSM strategy could provide good guidance for environmental protection methodologies in the future.

Diverse Applications of Biomass-Derived 5-Hydroxymethylfurfural and Derivatives as Renewable Starting Materials

This Review summarizes recent efforts to capitalize on 5-hydroxymethylfurfural (HMF) and related furans as emerging building blocks for the synthesis of fine chemicals and materials, with a focus on advanced applications within medicinal and polymer chemistry, as well as nanomaterials. As with all chemical industries, these fields have historically relied heavily on petroleum-derived starting materials, an unsustainable and polluting feedstock. Encouragingly, the emergent chemical versatility of biomass-derived furans has been shown to facilitate derivatization towards valuable targets. Continued work on the synthetic manipulation of HMF, and related derivatives, for access to a wide range of target compounds and materials is crucial for further development. Increasingly, biomass-derived furans are being utilized for a wide range of chemical applications, the continuation of which is paramount to accelerate the paradigm shift towards a sustainable chemical industry.

Intense multi-colored luminescence in a series of rare-earth metal-organic frameworks with aliphatic linkers

Two series of highly luminescent yttrium(iii), europium(iii) and terbium(iii) metal-organic frameworks containing diimine aromatic ligands and the dicarboxylate linker trans-1,4-cyclohexanedicarboxylate (chdc^2-) which can be described by the general formulas [M₂(bpy)₂(chdc)₃], where M = Y³⁺ (1), Eu³⁺ (2), and Tb³⁺ (3) and bpy = 2,2'-bipyridyl, and [M₂(phen)₂(chdc)₃], where M = Y³⁺ (4), Eu³⁺ (5), and Tb³⁺ (6) and phen = 1,10-phenanthroline, were synthesized and characterized. All compounds are based on the same dinuclear {M₂(L)₂(OOCR)₆} building blocks and possess a similar topology of the 3D framework with narrow pores. The chelate aromatic ligands act as efficient light-harvesting antennas for subsequent energy transfer to the emitting metal center (M = Eu³⁺, Tb³⁺) or intraligand photoemission (M = Y³⁺). As a result, the reported compounds display intense emission in the red (Eu³⁺), green (Tb³⁺) or blue (Y³⁺) regions representing three basic colors (RGB) of visible light. The measured quantum yields (QYs) of the solid-state luminescence for individual compounds were found to be 63% (1), 46% (2), 59% (3), 2.3% (4), 55% (5) and 49% (6). The drastic reduction of the luminescence efficiency for 4 is explained by the strong disorder of phen ligands. The high thermal stability (up to 300 °C) and exceptional moisture resistance of the bpy-based frameworks 1-3 were confirmed by TG and PXRD measurements. Various bimetal or trimetal compositions were also prepared for the bpy-series. The luminescence properties of these mixed-metal compounds depend on both the chemical composition and excitation wavelength (λ_ex). Remarkably, pure white emission with color temperature = 6126 K was achieved for [Y_1.68Eu_0.08Tb_0.24(bpy)₂(chdc)₃] at λ_ex = 360 nm with QY = 20%. The reported results suggest that the obtained coordination framework series is a convenient platform for the design of highly efficient light emitting materials with tunable properties.