4′–phenyl −2, 2′: 6′, 2′’-terpyridine derivatives as metal chemosensors. Chelation and fluorescence capabilities towards Zn(II), Cd(II), and Hg(II) from experiment and theory

IF 4.1 3区化学 Q2 CHEMISTRY, PHYSICAL Journal of Photochemistry and Photobiology A-chemistry Pub Date : 2024-07-23 DOI:10.1016/j.jphotochem.2024.115885

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Abstract

4′-phenylterpyridine (TPY) involves four conjugated rings, leading to a multi-resonant chromophore with exceptional luminescent features. Further functionalization of the 4′-phenyl moiety enables a versatile set of chemosensors. In the series, the optical transitions remain similar, where λ_max ranges from 253 to 269 nm, with emissions from 357 to 365 nm. Calculations of the natural transition orbitals NTOs deliver the localized hole-electron densities, indicating that the electronic transitions vary as a local-excitation (LE), charge transfer (CT), and mixed LE-CT along with the set. We employ the energy decomposition analysis to evaluate the possible coordination toward Zn(II), Cd(II), and Hg(II) cations, showing a favorable formation of complexes, where the interaction nature exhibits a ∼ 49 and ∼ 50 % electrostatic and orbital character for the Zn(II), Cd(II) and Hg(II) centers. Furthermore, the density deformation channels confer an explicit picture of the bonding scheme, denoting π- and σ-bonding contributions.

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4′-phenyl -2, 2′: 6′, 2′'-terpyridine 衍生物作为金属化学传感器。从实验和理论看锌（II）、镉（II）和汞（II）的螯合和荧光能力

4′-phenylterpyridine (TPY) 包含四个共轭环，是一种具有特殊发光特性的多共振发色团。进一步对 4′-苯基分子进行官能化处理后，就能产生一系列用途广泛的化学传感器。在该系列中，光学转变仍然相似，λmax 范围为 253 至 269 nm，发射波长为 357 至 365 nm。对自然过渡轨道 NTO 的计算得出了局部空穴-电子密度，表明电子跃迁随着局部激发 (LE)、电荷转移 (CT) 和混合 LE-CT 的集合而变化。我们利用能量分解分析来评估 Zn(II)、Cd(II) 和 Hg(II) 阳离子的可能配位，结果显示形成的配合物是有利的，其中 Zn(II)、Cd(II) 和 Hg(II) 中心的相互作用性质表现出 ∼ 49% 和 ∼ 50% 的静电和轨道特性。此外，密度形变通道提供了成键方案的清晰图景，表示π键和σ键的贡献。

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来源期刊

Journal of Photochemistry and Photobiology A-chemistry 化学-物理化学

CiteScore

7.90

自引率

7.00%

发文量

580

审稿时长

48 days

期刊介绍： JPPA publishes the results of fundamental studies on all aspects of chemical phenomena induced by interactions between light and molecules/matter of all kinds. All systems capable of being described at the molecular or integrated multimolecular level are appropriate for the journal. This includes all molecular chemical species as well as biomolecular, supramolecular, polymer and other macromolecular systems, as well as solid state photochemistry. In addition, the journal publishes studies of semiconductor and other photoactive organic and inorganic materials, photocatalysis (organic, inorganic, supramolecular and superconductor). The scope includes condensed and gas phase photochemistry, as well as synchrotron radiation chemistry. A broad range of processes and techniques in photochemistry are covered such as light induced energy, electron and proton transfer; nonlinear photochemical behavior; mechanistic investigation of photochemical reactions and identification of the products of photochemical reactions; quantum yield determinations and measurements of rate constants for primary and secondary photochemical processes; steady-state and time-resolved emission, ultrafast spectroscopic methods, single molecule spectroscopy, time resolved X-ray diffraction, luminescence microscopy, and scattering spectroscopy applied to photochemistry. Papers in emerging and applied areas such as luminescent sensors, electroluminescence, solar energy conversion, atmospheric photochemistry, environmental remediation, and related photocatalytic chemistry are also welcome.