Abstract EN:

Photosynthesis is a complex reaction that leads to the conversion of light energy to chemical energy. Chapter I proposes a review of the up-to-date knowledge of the natural system. The work described thereafter deals with the synthesis of Ruthenium-Manganese complexes, as model compounds of the electron transfer for Photosystem II. Following a first synthetic route, described in chapter II, we obtained a mixture of two species. Although the latter could not be separated, analysis of the mixture with a variety of spectroscopic techniques led to the identification of a RuMn2 triad and a Ru2Mn complex. We then developped two new strategies toward the synthesis of a [(Bipy)2Ru(PyN3)-BpmpH]+ moiety, capable of chelating two Manganese ions. In the first approach, protecting the phenolic oxygen of NH2BpmpH via the formation of a Zinc dimer allowed the coupling reaction of the amine with an acyl chloride to proceed efficiently. In the second approach, NH2Ar(DPA)2 is first reacted with an acyl chloride bearing the Ruthenium complex, then an aromatic oxydation of the xylene ring is performed. During these studies, a serie of RBpmpH ligands, only differing one another by the electronic properties of the para group, were isolated. Syntheses and characterization of the corresponding dinuclear Manganese(II) complexes are summed up in chapter IV. Chapter V deals with EPR studies of the [(Bpmp)Mn2(OAc)2](ClO4) complex. We developed a new approach for the determination of the spin parameters of the S-state resulting from the magnetic interaction between the two Manganese(II) ions, which led to very accurate simulation of X- and Q-band EPR spectra and their temperature dependance. Preliminary results on high field experiments were obtained. To conclude, chapter VI reports on the storage of up to three oxidative equivalents starting with Manganese(II) complexes. During the course of these studies, X-ray structure of the [(TPEN)Mn(m-OAc)Mn(TPEN)](ClO4)3 complex was established.