The effect of functional groups in the aqueous-phase selective sensing of Fe(iii) ions by thienothiophene-based zirconium metal-organic frameworks and the design of molecular logic gates.

Title The effect of functional groups in the aqueous-phase selective sensing of Fe(iii) ions by thienothiophene-based zirconium metal-organic frameworks and the design of molecular logic gates.
Authors R. Dalapati; Ü. Kökçam-Demir; C. Janiak; S. Biswas
Journal Dalton Trans
DOI 10.1039/c7dt04130f
Abstract

The synthesis of four isoreticular, water-stable Zr(iv) metal-organic frameworks (MOFs) was conducted under solvothermal conditions by using thienothiophene-based ligands. The MOFs were fully characterized by XRPD analyses, FT-IR spectroscopy and TG analyses. The ligands were systematically modified with methyl and phenyl groups for tuning the fluorescence and hydrophobic behaviour of the MOFs. The photophysical properties of free ligands and the corresponding MOFs were investigated by steady-state as well as time-resolved fluorescence experiments. The MOFs containing ?-electron rich, conjugated thieno[3,2-b]thiophene units were employed for the sensing of metal ions. All the MOFs displayed high selectivity and sensitivity towards the sensing of biologically important Fe3+ ions in pure aqueous medium through the fluorescence quenching mechanism. Detailed experimental investigations suggest that the transfer of electrons from the electron-rich frameworks to the half-filled 3d orbitals of Fe3+ ions results in fluorescence quenching. Surprisingly, the electron acceptor methyl viologen (MV2+) ions exhibited a reverse trend in the quenching efficiency compared to the Fe3+ ions. Both the steric and electronic effects of the attached functional groups can be proposed to play determining roles in the fluorescence quenching mechanism. All the MOFs showed high photostability and reusability, which are beneficial for the long-term real-world detection of Fe3+ ions. Interestingly, the MOFs can be utilized to construct molecular logic gates for the efficient discrimination between Fe3+ and Fe2+ ions.

Citation R. Dalapati; Ü. Kökçam-Demir; C. Janiak; S. Biswas.The effect of functional groups in the aqueous-phase selective sensing of Fe(iii) ions by thienothiophene-based zirconium metal-organic frameworks and the design of molecular logic gates.. Dalton Trans. 2018. doi:10.1039/c7dt04130f

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Zirconium

See more Zirconium products. Zirconium (atomic symbol: Zr, atomic number: 40) is a Block D, Group 4, Period 5 element with an atomic weight of 91.224. Zirconium Bohr ModelThe number of electrons in each of Zirconium's shells is 2, 8, 18, 10, 2 and its electron configuration is [Kr]4d2 5s2. The zirconium atom has a radius of 160 pm and a Van der Waals radius of 186 pm. Zirconium was discovered by Martin Heinrich Klaproth in 1789 and first isolated by Jöns Jakob Berzelius in 1824. In its elemental form, zirconium has a silvery white appearance that is similar to titanium. Zirconium's principal mineral is zircon (zirconium silicate). Elemental ZirconiumZirconium is commercially produced as a byproduct of titanium and tin mining and has many applications as a opacifier and a refractory material. It is not found in nature as a free element. The name of zirconium comes from the mineral zircon, the most important source of zirconium, and from the Persian wordzargun, meaning gold-like.

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