Light-induced electron transfer in simple and supramolecular Ru-polypyridine complexes

Abstract: Akstract. In artificial photosynthesis the chief research goal is to duplicate the function of the photosynthetic unit in nature hut not its structural subunits. In this paper, light-induced electron-transfer processes of Ru-polypyridines as energy-storing systems, in the presence of suitable acceptors and catalysts, are described. New highly photostable photosensitizers are presented. A new approach using supramolecular (non-covalently) connected assemblies in addition to covalently linked systems for energy-… Show more

“…Natural as well as artificial photosynthesis possesses, − as primordial characteristics, efficient light-harvesting units for the conversion of solar energy. The basic reaction to be realized is light-induced charge separation leading to the cleavage of water.…”

“…The basic component for such systems is a good sensitizer (S = D) for electron transfer, such as porphins, ruthenium polypyridines, dyes, and semiconductors. In this Account we will treat first and exclusively functionalized ruthenium polypyridines and then more complex RuL 3 (D)−viologen (A) polyads, especially the ones developed in our group. With suitable acceptors such as viologens, electron transfer occurs in these systems.…”

“…A second route uses halopyridines and Cu(0) or Ni(0), and the third access employs Pd(0), halopyridines, and pyridyl-boric acids (Suzuki reaction). A complete construction of the second ring of 2,2‘-bipyridines is possible with the Kröhnke reaction. , …”

“…More complex D−A-linked ligands 6 will be treated below. From these ligands RuL 3 or RuL 2 L complexes were prepared …”

“…The synthetic strategy we employed for ruthenium polypyridines 6 is shown in Scheme , ,− which shows a general method for the synthesis of trishomoleptic (such as A) and bisheteroleptic Ru(II) complexes (such as B) (DMSO = dimethyl sulfoxide, λ−λ = bpz = 1,4-bipyridazine, or μ−μ = bpy = 2,2‘-bipyridine).

2

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Ruthenium Polypyridine Complexes. On the Route to Biomimetic Assemblies as Models for the Photosynthetic Reaction Center

“…Natural as well as artificial photosynthesis possesses, − as primordial characteristics, efficient light-harvesting units for the conversion of solar energy. The basic reaction to be realized is light-induced charge separation leading to the cleavage of water.…”

“…The basic component for such systems is a good sensitizer (S = D) for electron transfer, such as porphins, ruthenium polypyridines, dyes, and semiconductors. In this Account we will treat first and exclusively functionalized ruthenium polypyridines and then more complex RuL 3 (D)−viologen (A) polyads, especially the ones developed in our group. With suitable acceptors such as viologens, electron transfer occurs in these systems.…”

“…A second route uses halopyridines and Cu(0) or Ni(0), and the third access employs Pd(0), halopyridines, and pyridyl-boric acids (Suzuki reaction). A complete construction of the second ring of 2,2‘-bipyridines is possible with the Kröhnke reaction. , …”

“…More complex D−A-linked ligands 6 will be treated below. From these ligands RuL 3 or RuL 2 L complexes were prepared …”

“…The synthetic strategy we employed for ruthenium polypyridines 6 is shown in Scheme , ,− which shows a general method for the synthesis of trishomoleptic (such as A) and bisheteroleptic Ru(II) complexes (such as B) (DMSO = dimethyl sulfoxide, λ−λ = bpz = 1,4-bipyridazine, or μ−μ = bpy = 2,2‘-bipyridine).

2

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Ruthenium Polypyridine Complexes. On the Route to Biomimetic Assemblies as Models for the Photosynthetic Reaction Center

Effektive Ladungstrennung in einem intermolekularen Komplex aus Elektronendonor und doppelarmiger Triade: ein Modellsystem für die Kontrolle des Elektronentransfers durch Umgebungseffekte

Effective Charge Separation in Intermolecular Complexes of an Electron Donor and a Doubly Branched Triad Assembly: A Model System for Environmental Effects Controlling Electron Transfer