Artificial photosynthetic systems that contain light-harvesting coordination complexes may
one day replace conventional non-renewable sources of energy with renewable solar …

Artificial photosynthetic systems can collect and transform solar energy into chemical
energy. Inspired by natural photosynthesis, molecular artificial systems are commonly …

Room‐temperature luminescent CoIII complexes (1 and 2) are presented that exhibit intense
ligand‐to‐metal and ligand‐to‐ligand charge transfer absorption in the low‐energy UV …

Since the initial report by Lehn et al. in 1979, ruthenium tris (bipyridine)([Ru (bpy) 3] 2+) and
its numerous derivatives were applied as photosensitizers (PSs) in a large panel of …

The present article deals with the structurally and spectroelectrochemically characterized
newer class of ruthenium-azoheteroarenes [RuII (Ph-trpy)(Cl)(L)] ClO4,[1] ClO4–[3] ClO4 (Ph …

In order to expand and exploit the useful properties of d6-iron (II) and d5-iron (III) complexes
in potential magnetic, photophysical, or magnetooptical applications, crucial ligand …

Luminescent complexes of earth-abundant first-row transition metals are of renewed, broad
interest due to their spectroscopic and photochemical properties as well as emerging …

The pH-switchable room-temperature near-infrared (NIR) phosphorescence emission based
on ruthenium (II) polypyridyl complexes has been very rarely reported, even though it is very …

A novel N^ N^ N tridentate ligand dgpy (dgpy= 2, 6-diguanidylpyridine) was synthesized by
a Pd-catalyzed C–N bond-forming reaction. A novel family of [RuII (tpy')(dgpy)](PF6) 2 (1 and …

A high-temperature, microwave synthesis of [Ru (qpy) 3] 2+(qpy= 4, 4′: 2′, 2′′: 4′′,
4′′′-quaterpyridine) affords the photosensitiser in quantitative yield. The complex …