Two anthracene-based complexes [Ir(pbt) 2 (aip)]Cl (1) and [Ir(pbt) 2 (aipm)]Cl (2) have been synthesized based on the ligands aip = 2-(9-anthryl)-1H-imidazo[4,5-f ][1,10]phenanthroline, aipm = 2-(9-anthryl)-1 -methyl-imidazo[4,5-f ][1,10]phenanthroline, and pbtH = 2-phenylbenzothiazole in order to explore both the influence of the substituent group R 1 (R 1 = H in 1 and CH 3 in 2) on photo-oxidation activity and photo-oxidation-induced luminescence. Both 1 H NMR spectra and ES mass spectra indicate that the anthracene moiety in complex 1 can be oxidized at room temperature upon irradiation with 365 nm light. Thus, this complex shows photooxidation-induced turn-on yellow luminescence. Compared to 1, complex 2 incorporates an R 1 = CH 3 group, resulting in very weak photo-oxidation activity. On the basis of experimental results and quantum chemical calculation, we report the differences between 1 and 2 in both photo-oxidation behavior and the related luminescence modulation and discuss the relationship between photo-oxidation activity and substituent group R 1 in these complexes.
Based on ligands dfppyH and pidpyH, cyclometalated Ir(iii) complexes [Ir(dfppy)(pidpyH)](PF) (1·PF) and [Ir(dfppy)(pidpy)] (2) have been synthesized. The crystal structures indicate that each {Ir(dfppy)} unit is coordinated by a neutral ligand pidpyH in 1·PF, while by a pidpy anion in 2. The packing structure of 1·PF only exhibits electrostatic interactions and van der Waals interactions among [Ir(dfppy)(pidpyH)] cations and PF ions. In contrast, the neighboring molecules in 2 are linked into a supramolecular chain structure through aromatic stacking interactions between two dfppy ligands. In solution, 1·PF and 2 show acid/base-induced structural transformation due to the protonation/deprotonation of their pyridyl groups and/or imidazole units, which can be confirmed by their H NMR spectra. At room temperature, compounds 1·PF, 2 and pidpyH in CHCl reveal TFA-induced luminescence switching behaviors, from a non-luminescence state to a luminescence state with an emission at 582 nm for both 1·PF and 2, and emission switching from 392 nm to 502 nm for pidpyH. These switching behaviors are associated with the protonation of pyridyl groups and/or imidazole units in 1·PF, 2 and pidpyH. Moreover, compounds 1·PF and 2 were used as photosensitizers (PS) for reduction of water to hydrogen under the same experimental conditions. It was found that the amount of evolved hydrogen and the PS turnover number are 512 μmol and 102 for 1·PF, and 131 μmol and 26 for 2, respectively. Thus, compound 1·PF has better photocatalytic activity than 2. In this paper, we discuss the modulation of luminescence and photocatalytic activities of 1·PF and 2 by varying the coordination mode and/or protonation extent of pidpyH/pidpy ligands.
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