Novel Heteroleptic Ruthenium(II) Complexes with 2,2′- Bipyridines Containing a Series of Electron-Donor and Electron-Acceptor Substituents in 4,4′-Positions: Syntheses, Characterization, and Application as Sensitizers for ZnO Nanowire-Based Solar Cells

Abstract: A novel series of complexes of the formula [Ru­(4,4′-X2-bpy)2(Mebpy-CN)]­(PF6)2 (X −CH3, −OCH3, −N­(CH3)2; Mebpy-CN = 4-methyl-2,2′-bipyridine-4′-carbonitrile) have been synthesized and characterized by spectroscopic, electrochemical, and photophysical techniques. Inclusion of the electron-withdrawing substituent −CN at one bpy ligand and different electron-donor groups −X at the 4,4′-positions of the other two bpy ligands produce a fine tuning of physicochemical properties. Redox potentials, electronic absor… Show more

“…Mixing between MOs centered in the metal center and 4,4′-(N(CH 3 ) 2 ) 2 -bpy ligands has been recently reported for heteroleptic Ru bipyridyl complexes. 35 On the other hand, this stabilization of the HOMOs increases in the series when going from 1 to 3 and correlates with the trend observed in the maximum absorption of the lowest energy MLCT bands, as described in the UV-vis spectroscopy section. In complex 1, the LUMO is delocalized over the ligands with a main contribution of (bpy-OMe) and equal contributions from the pyridyl rings of trpy, while in complexes 2 and 3 the LUMOs are mainly centred in the trpy rings with a concomitant energy stabilization respect to 1.…”

New ruthenium polypyridyl complexes as potential sensors of acetonitrile and catalysts for water oxidation

“…Mixing between MOs centered in the metal center and 4,4′-(N(CH 3 ) 2 ) 2 -bpy ligands has been recently reported for heteroleptic Ru bipyridyl complexes. 35 On the other hand, this stabilization of the HOMOs increases in the series when going from 1 to 3 and correlates with the trend observed in the maximum absorption of the lowest energy MLCT bands, as described in the UV-vis spectroscopy section. In complex 1, the LUMO is delocalized over the ligands with a main contribution of (bpy-OMe) and equal contributions from the pyridyl rings of trpy, while in complexes 2 and 3 the LUMOs are mainly centred in the trpy rings with a concomitant energy stabilization respect to 1.…”

New ruthenium polypyridyl complexes as potential sensors of acetonitrile and catalysts for water oxidation

“…Second, the regular periodic structure of the PPV−Ru system illustrated in Figure 2b certainly represents an idealization with respect to the periodicity of the attached photosensitizer, the assumption of a straight polymer, the exact length of the linker between polymer and photosensitizer and the representation of the aqueous environment by a finite number of explicit water molecules in just one structure. Still, our DFT calculations yield a HOMO‐LUMO gap of the Ru photosensitizer that is by roughly 1 eV larger than the experimentally derived value which has also been found in similar systems [64,65] …”

“…Still, our DFT calculations yield a HOMO-LUMO gap of the Ru photosensitizer that is by roughly 1 eV larger than the experimentally derived value which has also been found in similar systems. [64,65] Time-dependent density functional theory, on the other hand, is well established to access and predict the light-driven processes in transition metal complexes [44,66] and soft matter embedded light-harvesting units. [67] Through TDDFT, individual excited states and their properties such as oscillator strength and electron density become accessible, which allows fundamental insights into the mechanisms of light-driven processes such as electron or hole injection.…”

Coupling of photoactive transition metal complexes to a functional polymer matrix**

“…Still, our DFT calculations yield a HOMO-LUMO gap of the Ru photosensitizer that is by roughly 1 eV larger than the experimentally derived value which has also been found in similar systems. 64,65 Time-dependent density functional theory, on the other hand, is well established to access and predict the light-driven processes in transition metal complexes 44,66 and soft matter embedded light-harvesting units . 67 Through TDDFT, individual excited states and their properties such as oscillator strength and electron density become accessible, which allows fundamental insights into the mechanisms of light-driven processes such as electron or hole injection.…”

Coupling of photoactive transition metal complexes to a functional polymer matrix